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ON E P L A N E T MA N Y P E OP L E
www.unep.org
United NationsEnvironment Programme
P.O.Box 30552,Nairobi 00100,Kenya
Tel:(+254)20 621234
Fax:(+254)2 0 623927
E-mail:[email protected]
Web:www.unep.org
O N E P L A N E T
M A N Y P E O P L E
Atlas of Our Changing Environment
Through text,illustrati
photographs,this pub
humanity’spastand p
The primary focusis o
overthe last30 years,i
human geography.Th
the Earth – AStory of C
history of the planeta
species,Homo sapien
modern era.
The secondchapter,Pe
Influenceson the Plan
overpopulation increa
resourcesanddetailsh
approachesto utilizing
introducesconceptsof
ecosystemsandecore
biodiversity including
providesageneralove
consumption andextr
implicationsof theirus
The thirdchapter,Hum
Visualising Change ov
imagesto showhowh
continue to make,obs
the globalenvironme
in:the atmosphere,inc
pollution;oceansandc
wetlandsandwaterpo
fires;cropland;grassla
including polarregion
The chaptersummariz
human impacts,the dr
changes,and,in some
covershowvariousenv
affectpeople,both neg
The finalchapter,Natu
Events,illustrateschan
such asearthquakes,v
climatichazardsinclud
hurricanes,aswellas in
andindustrialacciden
in technology have led
eventsandfaster reac
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the damage thatthey
Suggestionsformitiga
environmentalchange
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serving asan early wa
change andas abasis
individualactionsaime
promoting the well-be
Increasing concern as to how human activities impact the Earth has led to documentation
and quantification of environmental changes taking place on land,in the water,and in the air.
Through a combination of ground photographs,current and historical satellite images,and
narrative based on extensive scientific evidence,this publication illustrates how humans have
altered their surroundings and continue to make observable and measurable changes to the
global environment.This publication underscores the importance of developing,harnessing
and sharing technologies that help provide deeper understanding of the dynamics of
environmental change.The words and pictures within these pages also serve as a vivid
reminder that this planet is our only current home, and that sound policy decisions and
positive actions by societies and individuals are needed to sustain the Earth and the well-
being of its inhabitants.The information we provide will not only be useful in the context of
the selected locations,but will also underscore the intrinsic value of the harnessing,
visualizing and communicating technologies to gain a deeper understanding of the dynamics
and impacts of our environmental changes.A t l a s of
O ur C h a n gi n gE nvi r onm en t
by DavidPape,NASA/GoddardSpace FlightCenter
tion Studio; Iceberg reflection,ChristopherUglow,
tsconsuming leaf,Pacharin Saenyan,Stillpictures; Crowd,
eson sand,Jan Schilthuizen,Stillpictures; Landsatimage
eca,15 Sep1999,Courtesy UNEP/GRIDSioux Falls.
es,Valery Shapurau,Stillpictures.
mage of Banda Aceh,Indonesia,10 January 2003,
aging; Children on tree,Shi Liang Wang,Stillpictures;
hn F.NeidlingerIII,Stillpictures; AsterSatellite Image of
a,courtesy NationalCenterforEarth Resources
cience,26 Aug 2000; People aroundtree,Chamaipom
ctures.
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i
Copyright 2005, United Nations Environment Programme
ISBN: 92-807-2571-8
This publication may be reproduced in whole or in part and in any form for educational or non-profit purposes without special permission from the copy-right holder, provided acknowledgement of the source is made. UNEP and the authors would appreciate receiving a copy of any publication that uses thisreport as a source.
No use of this publication may be made for resale or for any other commercial purpose whatsoever without prior permission in writing fromthe United Nations Environment Programme.
United Nations Environment ProgrammePO Box 30552, Nairobi, KenyaTel: +254 20 621234Fax: +254 20 623943/44http://www.unep.orghttp://www.unep.net
United Nations Environment ProgrammeDivision of Early Warning and Assessment-North America47914 252nd Street, USGS National Center for Earth ResourcesObservation and Science (EROS)Sioux Falls, SD 57198-0001 USA Tel: 1-605-594-6117Fax: [email protected] www.na.unep.net
For bibliographic and reference purposes this publication should be referred to as:
UNEP (2005), “One Planet Many People: Atlas of Our Changing Environment.”Division of Early Warning and Assessment (DEWA)United Nations Environment Programme (UNEP)P.O. Box 30552Nairobi, Kenya
This book is available from Earthprint.com, http://www.earthprint.com.
DISCLAIMER
The views expressed in this publication are not necessarily those of the agencies cooperating in this project. The designations employed and the presenta-tions do not imply the expression of any opinion whatsoever on the part of UNEP or cooperating agencies concerning the legal status of any country, terri-tory, city, or area of its authorities, or the delineation of its frontiers or boundaries.
Mention of a commercial company or product in this report does not imply endorsement by the United Nations Environment Programme. The use of information from this publication concerning proprietary products for publicity or advertising is not permitted. Trademark names and symbols are used inan editorial fashion with no intention of infringement on trademark or copyright laws.
We regret any errors or omissions that may have been unwittingly made.
Reprinted by Progress Press Company Limited, Malta.
Distribution by SMI (Distribution Services) Ltd. UK.
This publication is printed on chlorine free, acid free paper made of wood pulp from sustainable managed forests.
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O N E P L A N E T
M A N Y P E O P L EAtlas of Our Changing Environment
United Nations Environment Programme
2005
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v
To obtain a copy of this publication, please contact: Ashbindu Singh, Regional CoordinatorUNEP/GRID - Sioux FallsUSGS National Center for Earth ResourcesObservation and Science(EROS)47914 252nd Street Sioux Falls, SD 57198Phone: 1 605 594-6117Fax: 1 605 594-6119E-mail: [email protected]
Editorial and Production Team
UNEP
Ashbindu Singh, Team Coordinator
USGS
Thomas R. Loveland, Writer
SAIC, TSSC to the USGS
Mark Ernste, Remote Sensing/GIS Scientist
Kimberly A. Giese, Design and Layout
Rebecca L. Johnson, Editor
Jane S. Smith, Editorial Assistant/Support
John Hutchinson, Cartographer
Eugene Fosnight, Writer
Consultant
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Jane Barr, Writer
Eugene Apindi Ochieng, Remote Sensing/GIS Analyst
UNEP–Nairobi
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United Nations Environment ProgrammeRegional Office for North AmericaDivision of Early Warning and Assessment-North
America1707 H. Street, N.W., Suite 300
Washington, DC 20006Tel: 1-202-785-0465Fax: 1-202-785-2096
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FOREWORD ................................................................................................................................................................................vi
PREFACE ................... ..................... ..................... ..................... ..................... ..................... ..................... ..................... .............. vii
1 Introducing the Planet – A Story of Change................... ..................... ..................... ..................... ..................... ................... 1
References .................... ..................... ..................... ..................... ..................... ..................... ..................... ................... 9
2 People and Planet – Human Influences on the Planet .................... ..................... ..................... ..................... ..................... 13
2.1 World Population .................... ..................... ..................... ..................... ..................... .................... ..................... 16
2.2 Culture ................... ..................... ..................... ..................... ..................... ..................... ..................... ................. 21
2.3 Land Use and Degradation ................... ..................... ..................... ..................... .................... ..................... ....... 25
2.4 Ecoregions and Ecosystems ..................... ..................... ..................... ..................... ..................... ..................... ... 32
2.5 Biodiversity, Invasive Species, and Protected Areas ..................... ..................... .................... ..................... ....... 352.6 Energy Consumption and Resource Extraction .................. ..................... ..................... ..................... ................. 43
References .................... ..................... ..................... ..................... ..................... ..................... ..................... ................. 62
3 Human Impacts on the Planet – Visualising Change over Time ................... ..................... ..................... ..................... ....... 67
3.1 Atmosphere ................... ..................... ..................... ..................... ..................... ..................... ..................... .......... 72
3.2 Coastal Areas .................... ..................... ..................... ..................... ..................... .................... ..................... ....... 90
3.3 Water .................... ..................... ..................... ..................... ..................... ..................... .................... ................... 118
3.4 Forests ..................... ..................... ..................... ..................... ..................... ..................... ..................... ............... 156
3.5 Cropland ..................... ..................... ..................... ..................... ..................... .................... ..................... ............ 194
3.6 Grasslands ................... ..................... ..................... ..................... ..................... .................... ..................... ............ 216
3.7 Urban Areas .................. ..................... ..................... ..................... ..................... ..................... ..................... ........ 230
3.8 Tundra and Polar Regions ..................... ..................... ..................... ..................... .................... ..................... ..... 260
References .................... ..................... ..................... ..................... ..................... ..................... ..................... ............... 280
4 Natural and Human-induced Extreme Events ................... ..................... ..................... ..................... ..................... ............ 289
4.1 Geo-hazards .................. ..................... ..................... ..................... ..................... ..................... ..................... ........ 291
4.2 Climatic Hazards ..................... ..................... ..................... ..................... ..................... .................... ................... 300
4.3 Industrial Hazards .................... ..................... ..................... ..................... ..................... .................... ................... 307
References .................... ..................... ..................... ..................... ..................... ..................... ..................... ............... 314
EPILOGUE ..................... ..................... ..................... ..................... ..................... ..................... ..................... ..................... ........ 316
ACRONYMS AND ABBREVIATIONS ................... ..................... ..................... ..................... ..................... ..................... ............ 318
ACKNOWLEDGEMENTS .................... ..................... ..................... ..................... ..................... ..................... ..................... ........ 320
Table of Contents
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People affect the environment as they interact with it, using it for food,shelter, and recreation and making
changes to better suit their needs, purpos-es, and inclinations. Through our ability to adapt natural resources to our use, wehave altered the environment in ways that
can now be objectively measured. Ourpresence on the Earth can be seen throughchanges on the landscape, as viewed fromspace. This publication presents imagesfrom space that portray the nature andextent of our impact on the planet.
Change is inevitable and an integralpart of our planet, our environment, andeven us. Our ability to adapt to diversesurroundings has allowed us to overcomemany environmental constraints and tailorthe planet to our benefit. We harnessedfire, cultivated plants and domesticated ani-mals. We built homes, then villages, andthen cities. We became “hewers of wood
and drawers of water.” We built tools anddiscovered how to quarry rocks and latermetals. Each advance allowed us to furtheradapt to and affect the environment that shaped us.
Our ability to act positively to safeguardour heritage and natural wealth may be
affected by the consequences of our suc-cess, however. As our numbers haveincreased, we have also evolved socially and culturally, applying different beliefsand practices to living in and using theenvironment. What we do affects those faraway from us, even those separated from
us by mountains, deserts, and oceans. Ouractivities change the planet in ways that affect our health as well as the health of theplants and animals upon which we depend.
We harvest the seas, consume water andenergy resources, and convert forests intopasture and cropland. We must be everconscious of the potential to overusethe land and stress it in ways that it cannot bear.
Our growing populations and settle-ments make life easier in some ways, but also make us more vulnerable to massiveearthquakes, volcanic eruptions, and otherdisasters. Imagine what would happen in
Italy today if Vesuvius erupted on the samescale it did when it destroyed Pompeii.
We have gravitated to the shores, mak-ing ourselves more vulnerable to stormsand hurricanes. We have settled alongrivers, making ourselves more vulnerableto floods. We have spread into marginal
climates, making ourselves more vulner-able to drought. Wildfires threaten someof our cities and settlements, just as they do our forests and croplands. Each of these events can affect hundreds of thou-sands of people, and the cost of protectingourselves and reducing the risk of disaster
continues to increase. Our own activitiescan also lead to disasters such as oil spillsand nuclear and industrial accidents that can devastate as much as any natural event.
Our dilemma is to avoid the most prob-lematic consequences without constrainingour need and ability to provide the world’sinhabitants with the environment andresources that will enable every person topursue an equitable life with all that such alife entails.
The images presented here show boththe positive and negative impacts of hu-man life on Earth. We hope also they willprovide food for thought, as we seek ways
to balance our use of the Earth’s resources with the need to sustain the environmentsthat produce them and support the livingsystems that we value so highly.
Foreword
Klaus Töpfer, Ph.D.
Executive Director United Nations Environment Programme
Charles G. Groat, Ph.D.
Director United States Geological Survey
Ghassem Asrar, Ph.D.
Science Deputy Associate Administrator National Aeronautics
and Space Administration
John Townshend, Ph.D.
University of Maryland Chair, Advisory Committee
UNEP/DEWA–North America
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Our population is growing, yet ourland base is currently fixed. Witheach new inhabitant comes a
need to make more modifications to theEarth’s environment. The impacts of thesemodifications may be both detrimental
and beneficial. For example, we estimatethat the Earth is losing 15 million hectaresof tropical forest land per year, a loss that has a negative effect on biodiversity. At thesame time, much of this deforested landis being converted to agricultural land tofeed our growing population; this is a posi-tive effect.
In the past 30 years—since the UnitedNations Conference on the Human Envi-ronment in Stockholm in 1972—we havemade a concerted effort to understand thelimits of the Earth’s bountiful resources
and have taken actions to preserve andsustain them. This publication illustratessome of the changes we have made to theenvironment in the recent past. It servesboth as an early warning for things that may come and as a basis for developing
policy decisions that can help sustain theEarth’s and our own well-being.
The first chapter of this atlas provides ashort environmental history of the world,one that illustrates how we got to where weare. Chapter 2 looks at the people and theplanet today, covering status and trendsover the last 30 years. Chapter 3 examinescommon issues regarding the Earth’s landcover and provides examples that illus-trate environmental status, trends, causesand consequences of change in the atmo-sphere, oceans and coastal zones, fresh-
water ecosystems, forests, cropland, grass-lands, urban areas, and tundra includingpolar regions. Chapter 4 illustrates changesthat are the result of extreme events, bothnatural and human-induced.
These examples raise many questions.
What is our likely environmental future? Are we better or less prepared for environ-mental change? What can people do tocreate a better future? The answers dependon the actions we choose to take.
Preface
Photo Credits (left Kern Khianchuen/UNEP
Dirk Heinrich/UNEPAimen Al-Sayya/UNEP
Steve Lonergan, Ph.D.
Director United Nations Environment Programme
Division of Early Warning and Assessment
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Topographic Map of the World
Credit: UNEP/NASA–GTOPO30
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Credit: Mark Ernste/UNEP/UNEP-GRID Sioux Falls
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I n our solar system, a single plan-
et—the Earth—supports human life. World population is increasing. Yet for the moment, the Earth remains
the only home for the human species. The way in which we care for this planet willaffect our future and the future of our chil-dren for generations to come.
Seen from space, the Earth is largely ablue planet around which swirls of whiteclouds constantly move. The Earth’s blueareas are its oceans. Oceans account forapproximately 70 per cent of the Earth’stotal surface area; the remaining 30 percent is land. The total size of the terrestrialsurface is approximately 149 million km2
(59.6 million square miles) (McNeill 2000;Grace n.d.).
The Earth’s land surface is rich in its variety. The highest point on the Earth’sland surface is Mount Everest, a breathtak-
ing 8 850 m (29 035 ft) above sea level.
The lowest point is the Dead Sea, which is,on average, about 400 m (1 312 ft) belowsea level. Terrestrial surfaces gain and loseheat much more quickly than oceans and aregion’s distance from the equator dramat-ically affects its climate. Landsnearest the equator tend to bethe warmest. Those that lie inthe middle latitudes typically have cooler climates, but arenot as cold as lands near thepoles. Some 20 per cent of the Earth’s terrestrial surface is covered by snow. Another 20 per cent is mountainous.
Just 30 per cent of the Earth’s land surface
is suitable for farming.Most people are accustomed to see-
ing the world around them as a relatively stable place, a generally nurturing environ-ment that has allowed the human race to
expand and develop in countless ways. In
fact, the Earth is constantly changing, asis our understanding of it (Figure 1.1).Some changes to the Earth’s surface occuron microscopic levels. Other changes takeplace on a scale so large as to be almost
inconceivable. Some types of change areinstantaneous, while other types occurslowly, unfolding over centuries, millennia,and even eons. Some changes are causedby the actions of people. Many others arepart of natural, inexorable cycles that canonly be perceived when cataclysmic eventsoccur or through painstaking research.
1
Credit: Blue Marble/UNEP/NASA (2002)
Introducing the PlanetA Story of Change
“e only thing permanentis change.”
— The Buddha (Siddartha Gau
Figure 1.1: The Earth’s surface has changed dramatically over time—as has our understanding of it. Early ideas
about the shapes and locations of the continents, forexample, were far different from what is known about the
land surface today.
Credit: Unknown/UNEP/Tapestries&More
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2
Agents of Environmental ChangeFrom the Earth’s earliest beginnings, forcessuch as climate, wind, water, fire, earth-quakes, volcanic eruptions, and the im-pacts of meteors and comets have shapedthe Earth’s terrestrial environments. These
same forces are at work today and will con-tinue far into the future. In addition, every living thing influences its environment andis influenced by it. One species may lessenthe chances for survival of the organisms it consumes for food. That same species, inturn, is affected by the actions of other organisms.
In order to survive, every organism must either adapt to its environment or modify the environment to make it more hospi-table. Humans are particularly adept at modifying their environments. By their ac-tions and interactions with the landscape,for example, people can increase the rangeof certain plant species, either by modify-ing existing environments or by dispers-ing seeds into new ones. Environmentalmodifications made by people may bebeneficial or detrimental to a few or many other species. Large-scale environmentalchanges may not benefit or be to the likingof people themselves (Nott 1996). As world
population has increased and the scopeand nature of technology has changed,people have brought about environmentalchanges that may seriously impact theirfuture well-being and even survival.
Humans began modifying their envi-
ronment a long time ago (Table 1.1). Evi-dence of the existence of our first human-oid ancestors dates to the Pliocene Epoch,
which extended from roughly 5 millionto 1.8-1.6 million years ago (Wikipedian.d.). These protohumans sought protec-tion from the elements and from preda-tors in natural shelters such as caves androck overhangs. Over time—and possibly
Table 1.1 – Approximate change of the Earth’s global vegetative cover in relation to human population
(Adapted from McNeill 2000).
Per cent of the Earth’s Vegetated Land Area
Year Forest and Human Population Woodland Grassland Pasture Cropland (Billions)
8000 B.C. 51 49 0 0 0.005
1700 A.D. 47 47 4 2 0.6
1900 43 40 10 6 1.6
1920 43 38 12 7 1.9
1940 41 35 16 8 2.3
1960 40 31 20 9 3.0
1980 38 26 25 11 4.4
1990 36 27 26 11 5.3
Throughout the Earth’s history, events have occurred that dramatically impacted life on our
planet. Five of those events stand out as having resulted in widespread extinctions, in some casesdestroying more than 90 per cent of all living things (Eldredge 2001):
• Around 440 million years ago, a relatively severe and sudden global cooling caused amass extinction of marine life (little terrestrial life existed at that time). An estimated 25per cent of the existing taxonomic families were lost. (A family may consist of a few tothousands of species.)
• Near the end of the Devonian Period, some 370 million years ago, a second majorextinction occurred. Roughly 19 per cent of the existing taxonomic families were
wiped out. It is uncertain whether climate change was a driving factor.
• About 245 million years ago, a third major extinction took place. Scientistsestimate that more than half (54 per cent) of all taxonomic families were lost.Climate change may have played a role, and that change may have been causedby a comet or meteor impacting the Earth.
• At the end of the Triassic Period, around 210 million years ago, roughly 23per cent of existing taxonomic families suddenly became extinct. This event occurred shortly after the appearance of the first dinosaurs and mammals. Itscauses are not yet fully understood.
• The fifth major extinction is the most well-known. It occurred about 65 mil-lion years ago at the end of the Cretaceous Period. The event led to the ex-tinction of all terrestrial dinosaurs and marine ammonites, along with many other species occupying many different habitats. All told, approximately 17per cent of all taxonomic families vanished in a very short time. Currently,the most widely accepted hypothesis to explain this mass extinction is that acomet or other large extra-terrestrial object struck the Earth. Another viewproposes that a great volcanic event, or series of events, disrupted ecosys-tems so severely worldwide that many terrestrial and marine species rapidly succumbed to extinction.
Five Major Events in the History of the Earth
Credit: Paul Fusco/UNEP/N
Credit: Chatree Wanasan/UNEP/Topfoto
Credit: Unknown/UNEP/Bigfoto
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influenced by the onset of colder weatherduring the Ice Ages—they created dwellingplaces for themselves in locations that hadno natural shelter.
The oldest surviving traces of such ahuman-made habitation date to about 2 million years ago from Olduvai Gorgein central Africa. There, a small circle of
stones was found stacked in such a way asto apparently have held branches in posi-tion. This early example of modificationof the environment was the work of Homo habilis , a tool–making human ancestor(Kowalski n.d.).
The Pleistocene Epoch, including thePaleolithic and Mesolithic Periods (Wiki-pedia n.d.), is usually dated from the endof the Pliocene to 10 000 years ago. ThePaleolithic Period, or Old Stone Age, is aterm coined in the 19th century to define
the oldest period in the history of human-kind. It lasted for some 2.5 million years,from the time human ancestors createdand used the first stone tools to the end of the last glacial period some 10 000 yearsago. Homo erectus , thought by many to bethe direct ancestor of modern humans,lived from approximately 2 million toaround 400 000 years ago. As a species,Homo erectus was very successful in devel-oping tools that helped in adapting tonew environments. They were pioneers indeveloping human culture, ultimately mov-ing out of Africa to populate tropical andsub-tropical environmental zones in theOld World, possibly as early as 1.8 million
years ago.
Homo erectus may also have masteredthe use of fire around 1.6 million yearsago (Mcrone 2000). Fire is an exception-
ally powerful tool. Since most animals,including large predators, are afraid of fire, early humans quickly discovered that campfires offered protection from attackduring the night. Control of fire allowedthem to move into colder regions as it pro-
vided warmth as well as security. Fire alsochanged the way food was prepared. Foodthat is cooked is less likely to carry diseaseorganisms and its softer texture makes it easier to eat, enhancing the survival of
young children and old members of a population.
The use of fire almost certainly in-creased during the Paleolithic Period. At that time, humans were primarily hunter-gatherers. The role of fire in modernhunter-gatherer cultures gives us some ideaof its importance during the Paleolithicand how people then most likely used
Fire—A Tool for Humankind
For thousands of years humans have used fire for:
Hunting
By setting fire to parts of the landscape, people were able to drive gameanimals into smaller, more confined areas that made hunting easier. Fire
was also used to drive animals into impoundments, chutes, river or lakes, orover cliffs. Fires also helped maintain open prairies and meadows by killingbushes and trees and encouraging rapid growth of grasses.
Improving plant growth and yields
Setting fires was a way to improve grass for grazing animals, both wild and
domestic, and to promote the growth of certain desirable plant species.
Protection
Fire was used to protect human habitations.
Collecting insects
Some tribes used “fire surrounds” to collect and roast crickets, grasshoppers,and moths. People also used fire smoke to quiet bees while collecting honey.
Managing pests
Fire was a handy tool for reducing or driving away insect pests such as fliesand mosquitoes as well as rodents. Fire was also effective for eliminatingundesirable plants.
Warfare and signaling
Fire was both an effective defensive and offensive weapon. Offensively, it was
used to deprive enemies of hiding places in tall grasses or underbrush. Useddefensively, fire could provide cover during an escape. Smoke signals helpedalert tribes to the presence of possible enemies or to gather forces to combat a foe. Large fires were set to signal a tribal gathering.
Clearing areas for travel
Fires were sometimes started to clear trails through dense vegetation.Burning helped to improve visibility in forests or grasslands for huntingand warfare.
Felling trees
Singed or charred trees were easier to fell and to work with.
Clearing riparian areas
Fire was used to clear vegetation from the edges of lakes and rivers.
Managing crops
Burning was later used to harvest crops and collect grass seeds. Fire alsohelped prevent abandoned fields from becoming overgrown and was em-ployed to clear areas for planting.
Credit: Jeff Vanuga/UNEP/NRCS
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impacted human lifestyles during theNeolithic Period. People left their tempo-rary rock and wooden shelters and beganto build more permanent homes in closeproximity to their farms and gardens,
where they started producing cereal grains which became an important part of theirdiet (Wadley and Martin 1993).
The Neolithic Period marked the begin-ning of true civilization, laying the foun-dations for major developments in socialevolution such as permanent settlements,
village life, formalized religion, art, archi-tecture, farming, and the production of advanced tools and weapons.
AgricultureThe first cultivation of wild grains some12 000 to 10 000 years ago turned hunter-
gatherers into farmers. The transition gavepeople a more abundant and dependablesource of food and changed the worldforever (Wilford 1997). The practice of agriculture first developed in the FertileCrescent of Mesopotamia (part of present-day Iraq, Turkey, Syria, and Jordan). Thisregion, which was much wetter then thanit is today, was home to a great diversity of annual plants and 32 of the 56 largest seed-producing grasses (Primal Seeds n.d.).
Around 11 000 years ago, much of theEarth experienced long dry seasons, prob-ably as a consequence of the major climatechange that took place at the end of the
last Ice Age. These conditions favoredannual plants that die off in the long dry season, leaving a dormant seed or tuber.Such plants put more energy into produc-ing seeds than into woody growth. Anabundance of readily storable wild grains
Figure 1.2: The Earth’s climate system involves
complex interactions among many elements and processes. Source: http://www.usgcrp.gov/usgcrp/Library/ ocp2004-5/ocp2004-5.pdf
Credit: T. Revter/UNEP/Topfoto
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and other edible seeds enabled hunter-gatherers in some areas to form perma-nently settled villages at this time (PrimalSeeds n.d.).
Theories vary as to how agriculturecame into being. Some scientists argue that rising global temperatures created favor-able conditions for agriculture. Otherspropose that an increase in seasonality after the last Ice Age encouraged people todomesticate plants. Still other researchersmaintain that ecological changes, social
development, or a growing human popula-tion intensified the exploitation of specificplant species (Baldia 2000).
Another suggestion is that an increasein carbon dioxide (CO2) on a global scalemay have played a critical role in bringingabout the synchrony of agricultural originsaround the globe (Sage 1995). Studieshave shown that a rise in atmospheric CO2 levels would have increased productivity of many plants by as much as 50 per cent.Furthermore, the water efficiency of culti-
vated plants increased, giving these plantsa competitive advantage over wild species.
A few scientists have proposed that cli-matic changes at the end of the last glacialperiod led to an increase in the size andconcentration of patches of wild cereals incertain areas (Wadley and Martin 1993).Increased availability of cereal grainsprovided people with an incentive to makea meal of them. Those who ate sizableamounts of cereal grains inadvertently discovered the rewards of consuming the
various chemical compounds that cerealgrains contain. As processing methods
such as grinding and cooking made cerealgrains more palatable, greater quantities
were consumed.
At first these patches of wild cereals
were protected and harvested. Peoplebegan to settle around these food sources.They gradually abandoned their nomadiclifestyle and began working together morecooperatively. Later, land was cleared,seeds were planted, and seedlings tendedto increase the quantity and reliability of cereal grain supply.
The rise of more permanent settle-ments intensified the domestication of
animals. The first candidate for domestica-tion, around 11 000 years ago, was prob-ably the dog. The cow was domesticated
around 10 000 years ago. Goats, sheep, andpigs were added to the growing list of do-mesticated animals around 8 000 years agoin western Asia. The horse was first domes-ticated in northern Russia around 4 000
years ago. Local equivalents and smallerspecies were increasingly domesticatedfrom 2 500 years ago (Wikipedia n.d.).
Farming and herding facilitated thegrowth of larger settled human popula-tions and led to increased competition forproductive lands, laying the foundation fororganized warfare. Food surpluses freedpeople to specialize in various crafts, suchas weaving, and, in larger communities,supported the emergence of a privilegedelite class. Archaeologists and historiansagree that the rise of agriculture, includingthe domestication of animals for food andlabor, produced the most important trans-formation in the interaction between theenvironment and human culture since thelast Ice Age—perhaps the most significant development in human history since thecontrol of fire (Wilford 1997).
Other milestones in human history that benefited people and changed the envi-ronment include:
The Bronze and Iron Ages (roughly 3300B.C. to 0 A.D.)
The world population approximately 5 000 years ago is estimated to have been about 7 million (IPC 2003a). This period saw theintroduction of metallurgy and mining, theinvention of the wheel, and the domestica-tion of the horse.
Classical Greece and Rome (0 to about 500 A.D.)
The world population at the beginning of this period was roughly 200 million (IPC2003a). During this period, glass was in-
vented and map-making developed.
Middle Ages to the Renaissance (500 toabout 1700)
By this point, world population had grownto about 250 million (IPC 2003a). Theclock, compass, telescope, thermometer,and barometer were developed, enablingpeople to expand their knowledge of theEarth and the Universe.
The Industrial Revolution (1700 – present)
By 1700, world population had risen toabout 600 million (IPC 2003a). This pe-riod witnessed the development of mecha-nization and the beginning of serious airpollution. Industrial changes also led to anagricultural revolution.
The Agricultural Revolution (1750 – 1900)
By 1750, world population had risen to 790million (IPC 2003a). In many countries the
way in which farmers produced food be-gan to change. New crops were exploitedusing new technologies such as the seeddrill and the iron plow. These methods of production produced greater quantities
of more nutritious foods, thereby improv-ing peoples’ diets and health. Better, moreefficient farming methods also meant that fewer people were needed to farm. As aresult, unemployed farmers formed a largenew labor force.
Credits: Michael Van Woert/UNEP/N
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The Green Revolution (1944 – present)
In 1944, world population reached 2 350million (Anon n.d.). A breakthrough in
wheat and rice production in Asia in themid-1960s, which came to be known as theGreen Revolution, symbolized the prog-ress of agricultural science as it developedmodern techniques for use in developingcountries. The Green Revolution had itsorigin in Mexico, where a “quiet” wheat revolution began in the 1940s(Borlaug 2000).
The goal of the Green Revolution isto enhance the efficiency of agriculturalprocesses in order to increase the produc-tivity of crops, thereby helping developingcountries to meet the needs of their grow-ing populations. The Revolution consistedof three primary elements: continuingexpansion of farming areas, double-crop-ping existing farmlands, and using geneti-cally improved seeds. Thanks to the GreenRevolution, we are able to grow more cropson less land.
However, the Green Revolution hasimpacted biodiversity and in some areas
water quality and coastal ecosystems. Thenew techniques encouraged large-scale in-dustrial agriculture at the expense of smallfarmers who were unable to compete withhigh-efficiency Green Revolution crops(Wikipedia n.d.). Nevertheless, the Green
Revolution is a success. We are able to feedmore people now, than ever before.
The Present Day World population now stands at 6 billionpeople (IPC 2003b). While global resourc-es were sufficient to support the Earth’shuman population as a whole prior to theIndustrial Revolution, individual groups oreven entire civilizations sometimes reachedenvironmental limits for a particular re-source; a number collapsed as a result of
unsustainable hunting, fishing, logging,or land use practices. The ever-increasingcultural globalization of the 20th and 21st centuries has brought with it globalizationof resource degradation, making current environmental problems an issue for theentire world rather than for individual,isolated groups. Although perceivedenvironmental limits can sometimes beovercome, neither science nor technology has yet made possible unlimited supplies of natural resources or depositories for waste(Casagrande and Zaidman 1999).
Moderate projections put world popula-tion at around 8 300 million by 2025 (Fig-ure 1.3), with the hope that it will stabilizeat roughly 10 000 to 11 000 million by theend of the century. It took approximately 10 000 years to expand global food pro-duction to the current level of about 5 000
million metric tonnes per year. By 2025,production must be nearly doubled. Inorder to feed the world’s people through2025, an additional 1 000 million metrictonnes of grain must be produced annu-ally. Most of this increase will have to besupplied by improving crop yields on landalready in production.
This will not be possible unless farm-ers worldwide have access to existing
high-yield crop production methods as well as biotechnological breakthroughsthat increase the yield, dependability, andnutritional quality of our basic food crops(Borlaug 2000).
Credit: Lee Tsunhua/UNEP/
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Human beings have been very successful in ex-ploiting the Earth’s resources. In the process, how-ever, they have brought about major changes in theEarth’s ecosystems, especially in recent years:
• half the world’s wetlands were lost during thelast century;
• logging and land use conversion have reducedforest cover by at least 20 per cent, and possibly asmuch as 50 per cent;
• nearly 70 per cent of the world’s major marinefish
stocks are either over-fished or being fished at thebiological limit;
• over the last half century, soil degradation has af-fected two-thirds of the world’s agricultural land. It is
estimated that each year some 25 000 million metrictonnes of fertile topsoil—the equivalent of all of the
wheat fields in Australia— is lost globally (Casagrande andZaidman 1999);
• each year, an estimated 27 000 species disappear from theplanet—approximately one every 20 minutes (Casagrande and
Zaidman 1999);
• the Earth now appears to be experiencing a sixth massextinction event that began about 50 000 years ago with the
expanding role of humans in the world (Recer 2004). Un-like past events, this mass extinction is being caused by
human activities such as transforming the landscape,overexploiting species, pollution, and alien species
introductions (Eldredge 2001);
• dams and engineering works have fragmented 60per cent of the world’s large river systems. They have so impeded water flow that the time it takes
for a drop of water to reach the sea has tripled;
• human activities are significantly alteringthe basic chemical cycles upon which all
ecosystems depend(Kirby 2000).
Historian J.R. McNeill recently wrote (McNeill 2000): “It is impos-
sible to know whether humankindhas entered a genuine ecologi-
cal crisis. It is clear enoughthat our current ways are
ecologically unsustain-able, but we cannot
know for how long we can yet sustain
Figure 1.3: Earth’s shrinking biosphere land area (ha)/capita
1900-2000 ADCurrently, the Earth is the only home we have. With each new person
added to our growing population, the amount of our living spacedecreases. Thus we have less land available but an increasing need to
feed more people. This puts more pressure on our limited resourcesand exacerbates changes in the environment . Source: Lund and Iremon-
ger 2000
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References
Anon. (n.d.). World population through the years. http://www.neopage.com/know/worldpop.htm on 19 March 2004.
Baldia, M. O. (2000). The origins of agriculture. Version 2.01.http://www.comp-archaeology.org/AgricultureOrigins.htm on19 March 2004.
Borlaug, N. E. (2000). The Green Revolution revisited and the roadahead. Special 30th Anniversary Lecture, The Norwegian NobelInstitute, Oslo, Norway, September 8, 2000, 23. http://www.nobel.se/peace/articles/borlaug/borlaug- lecture.pdf on 1
August 2004.
Casagrande, J. and Zaidman, Y. (1999). Defining a new balancebetween humans and the environment. Changemakers. http://
www.changemakers.net/journal/99September/index.cfm on18 March 2004.
Eldredge, N. (2001). The sixth extinction. ActionBioscience Journal. http://www.actionbioscience. org/newfrontiers/el-dredge2.html on 19 March 2004.
Grace, J. (n.d.). World Forests and Global Change. University of Edinburgh, The Institute of Ecology & Resource Management,Edinburgh, UK. http://www.ierm. ed.ac.uk/ierm/teaching/slides.pdf on 7 October 2004.
IPC (2003a). Historical estimates of world population. U.S. CensusBureau, Population Division, International Programs Center,Cambridge, UK. http://www.census. gov/ipc/www/worldhis.html on 19 March 2004.
IPC (2003b). Total midyear population for the world: 1950-2050.U.S. Census Bureau, Population Division, International Pro-grams Center, International Data Base, Cambridge, UK. http://
www.census.gov/ipc/www/worldpop.html on 19 March 2004.
Kirby, A. (2000). Humans stress ecosystems to the limit. BBC News,UK. http://news.bbc.co.uk/1/hi/sci/tech/926063.stm on 19March 2004.
Kowalski, W.J. (n.d.). http://www.personal.psu.edu/users/w/x/ wxk116/habitat/ on 19 March 2004.
Lund, H.G. and Iremonger, S. (2000). Omissions, commissions, anddecisions: the need for integrsted resource assessments. Forest Ecology and Management, 128(1-2): 3-10.
McNeill, J.R. (2000). Something new under the sun – An environ-mental history of the twentieth century world. W.W. Norton &Company, New York, USA, 421.
Mcrone, J. (2000). The discovery of fire. New Scientist. May 2000.http://www.btinternet.com/~neuronaut/webtwo_features_fire.htm on 18 March 2004.
NASA (2002). Blue Marble: Land Sur face, Shallow Water, andShaded Topography. http://visibleearth.nasa.gov/view_rec.php?vev1id=11656 on 18 August 2004.
Nott, A. (1996). Environmental Degradation. http://www.geocities.com/atlas/env/ on 6 October 2004.
Primal Seeds (n.d.). Agriculture Origins. http://www.primalseeds.org/agricult.htm on 19 March 2004.
Recer, P. (2004). Many species at risk of extinction. ResearchStudy. Associated Press. http://story.news.yahoo.com/news?tmpl=story&u=/ap/wildlife_gone on 19 March 2004.
Sage, R.F. (1995). Was low atmospheric CO2 during the Pleistocenea limiting factor for the origin of agriculture? Global ChangeBiology, 1:93-106. http://www.greeningearthsociety. org/Ar-ticles/origins.htm on 23 March 2004.
Tapestries and More. http://www.tapestries.cc/Imagehtm/gMap.html on 12 May 2004.
UNEP (2002). Global Environment Outlook 3 (GEO3) – Past,present and future perspectives. Earthscan, London, UK, 446.http://www.unep.org/geo/geo3/ on 4 March 2004.
US Global Change Research Program (2004). Our ChangingPlanet: The U.S. Climate Change Science Program for Fiscal
Years 2004 and 2005, 8. http://www.usgcrp.gov/usgcrp/Li-brary/ocp2004-5/ocp2004-5.pdf on 13 October 2004.
Wadley, G. and Martin, A. (1993). The origins of agriculture – a bio-logical perspective and a new hypothesis. Australian Biologist 6: 96 – 105. http://www.veganstraight- edge.org.uk/GW_paper.htm on 19 March 2004.
Wikipedia (n.d.). The free encyclopedia. http://en.wikipedia.org/wiki/Main_Page on 18 March 2004.
Wilford, J. N. (1997). New clues show where people made the great leap to agriculture. The New York Times Company. http://
www.spelt.com/origins.html on 19 March 2004.
Williams, G. W. (2001). References on the American Indian useof fire in ecosystems. U.S. Department of Agriculture: Forest Service, Washington, DC, USA. http://www. wildlandfire.com/docs/biblio_indianfire.htm on 15 March 2004.
them or what might happen if we do.” Inthe past, humanity trod relatively lightly onthe Earth, even though civilizations wereintensely concentrated in some places suchas Mesopotamia and the Nile River valley.Today, however, the evidence from spaceshows signs of the human presence inalmost every corner of the planet.
Global concern about the environment and the fate of the Earth emerged in the1970s, as did international initiatives to
address those concerns. In roughly the past 30 years, the environment has borne thestresses imposed by a four-fold increase inhuman population and an eighteen-foldincrease in world economic output (UNEP2002). Not surprisingly, when scientistscompare recent satellite images of theEarth’s surface with those taken one or sev-eral decades ago, the impact people havehad on the planet is obvious andoften disturbing.
This atlas vividly illustrates some of thechanges the human race has brought about on the Earth—both good and bad—overthe past 30 years. In doing so, it also servesas an early warning for environmentalevents that may occur. We hope it will beuseful as a basis for developing policy deci-sions and promoting individual actions tohelp sustain the Earth and ensure the well-being of its inhabitants.
Credit: Noguchi Yoshi/UNEP/Topfoto
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Nightlight Map of the World
Credit: UNEP/NOAA, NASA
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Credit: Busakorn Buranabunpo/UNEP/Topfoto
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2H
umans are a prolific and op-
portunistic species, amongthe most successful of all theEarth’s inhabitants. As the size
of the human population has increased,people have spread across the globe intoevery imaginable habitat. Throughout human history, people have demonstratedan uncanny ability to adapt to and survivein some very harsh places, including, most recently, outer space and the ocean—at least for short periods of time.
As human culture has evolved, peoplehave developed new ways of living in andusing their environment, and of helpingthemselves to all that the Earth has to
offer. Their ability to exploit the Earth’sseemingly endless resources has been a vi-tal key to the success of the human species.
However, many major advances inhuman culture—from the cultivation of crops and the development of cities tomodern technologies—have tended toinsulate people from the very environment that shaped them and upon which they depend. As a group, people have oftenforgotten that for every action taken thereis a reaction, an impact.
The impacts of human activities on
the Earth often have both negative andpositive components. For example, whenpeople convert forests or grasslands tocropland they improve the means by which to feed their ever-growing numbers. At the same time, they invariably reducebiological diversity in the converted areas.Over time, people have rarely been fully aware of the tremendous change they have wrought on the Earth or that their success-es have often been achieved at the expenseof other species and the environment.
Since the early 1970s, many excellent texts have been written about the plight of the world (Heywood 1995; Middleton
1997; WRI 2000; Chew 2001; FAO 2001;Harrison and Pearce 2001; IPCC 2001;McNeill 2001; UNEP 2002a). This atlassupplements these works by providingillustrations of both positive and negativehuman-caused changes that have takenplace on the Earth. Satellite images, to-gether with photographs, provide a unique view of how people are impacting the ter-restrial environment and what the conse-quences of environmental change meanin terms of human well-being. The images
and the changes they illustrate are diverse.But they are united by a common message:environmental change does matter.
The International Conference onPopulation and Development Programmeof Action noted that stabilization of world
People and PlanetHuman Influences on the Planet
Credit: Davoli Silvaho/UNEP/Topfoto
Credit: Ed Simpson/UNEP/PhotoSpin
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population is crucial to achieving sustain-able development. Population stabiliza-tion is also necessary for managing humanimpacts on the Earth’s environment andresources. In 1999, the Earth’s humanpopulation reached 6 000 million, havinggrown during the mid-1990s at a rate of 13per cent per year, with an average annualaddition of 78 million individuals. As of 1999, countries with populations of 100million or more included China, India, theUnited States, Indonesia, Brazil, Pakistan,
the Russian Federation, Bangladesh, Japan,and Nigeria. According to the medium variant of the United Nations’ populationestimates and projections, world popula-tion will reach 7 200 million by the year2015. Ninety-eight per cent of the popu-lation increase will take place in less-de- veloped regions of the world. Africa willexperience, by far, the most rapid rate of growth (Population Division 2000).
The overall impact that humans haveon the global environment is proportionalto the number of people on the Earth andthe average influence of each individual.If that overall impact is to be reduced, ad-dressing both of these factors is essential.
Change in distribution of world population 1900 and 2000. Source: http://www.newint.org/issue309/facts.html
Case Study: Parrot’s Beak
Between Sierra Leone and Liberia,there is a small strip of land belongingto Guinea known as the “Parrot’s Beak.”
As civil wars raged in Sierra Leoneand Liberia, hundreds of thousands of refugees have fled to relative safety inGuinea, many of them settling in theParrot’s Beak. The United Nations High
Commissioner for Refugees (UNHCR)estimates that the refugee populationconstitutes up to 80 per cent of the localpopulation there (UNEP 2000).
The 1974 image of the Parrot’sBeak in Guinea (left) shows the sur-rounding territory of Liberia and SierraLeone. Scattered throughout the deepgreen forest of the Parrot’s Beak regionare small flecks of light green, wherecompounds of villages with surroundingagricultural plots are located. Severaldark spots in the upper left of the imageare most likely burn scars.
The 2002 image (facing page) showsthe Parrot’s Beak region clearly defined
by its light green color surrounded by darker green forest. The light green
Credit: Unknown/UNEP/UNEP-GRID Geneva
Deforestation of indigenous palm trees inthe refugee camp has left barren hillsides.
Population Change
Europe(including
Russia)25%
Asia 60%
US 5%
Africa 4.5%Latin America 3% Others 2.5%
Asia Pacific(including formerSoviet Asia) 54%
Africa 10%
Latin America& Caribbean 8%
Middle East &North Africa 6%
North America 5%
Others 3%
Europe(including
Russia)14%
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A biome is a major ecological community of plants
and animals with similar life forms and environmen-tal conditions. Some of the Earth’s major terrestrialbiomes include forests, grasslands, deserts, rainforests, and tundra. Different biomes are the source
of different kinds of resources and processes (col-
lectively called ecosystem services) such as water,soil, oil, natural gas and other fuels, minerals andother raw materials, wildlife habitat, erosion control,nutrient cycling, water filtration, food production,
and genetic resources. The estimated global value
of the Earth’s biomes for ecosystem services aloneranges from US $16 trillion to US $54 trillion a year(Costanza et al. 1997).
color is the result of deforestation inthe “safe area” where refugees haveset up camp. Many of the refugeesintegrated into local villages, createdtheir own family plots, and expandedthe zones of converted forest area untilthey all merged into the larger definedarea. In the upper part of the 2002 im-age the forest devastation is especially
obvious, as areas that were green in the1974 image now appear gray. Logginginterests also moved into the higherelevations of this region, expanding thedeforested zone visible in the upperleft corner of the image.
Overall impoverishment of theenvironment of the Parrot’s Beak isdirectly related to the rapidly increas-ing population in the area, mainly dueto immigration, and a growth rate of about three per cent among the indig-enous population. Natural resourcesare being exploited to create more ar-able land for crops, wood for charcoal,firewood and construction materials,and commercial logging for revenue.
Source: UNEP 2000.
Credit: Unknown/UNEP/UNEP-GRID Geneva
Deforestation is evident on the hills sur-rounding the refugee camp.
Tropical and Subtropical Grasslands, Savannas, and Shrublands
Temperate Grasslands, Savannas, and Shrublands
Boreal Forests / Taiga
Temperate Conifer Forests
Temperate Broadleaf and Mixed Forests
Tropical and Subtropical Coniferous Forests
Deserts and Xeric Shrublands
Mangroves
Bare Rock / Ice
Mediterranean Forests, Woodlands, and Scrub
Tundra
Montane Grasslands and Shrublands
Flooded Grasslands and Savannas
Tropical and Subtropical Dry Broadleaf Forests
Tropical and Subtropical Moist Broadleaf Forests
Biomes
Source:World WildlifeFund TerrestrialEcoregions Dataset.
World Biomes
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A simple definition of world population is the num-
ber of people alive on the Earth at any given
point in time. World population reached
6 400 million in 2004 and it continues to grow by some
80 million each year (Table 2.1). Since the 1950s, China
has been the world’s most populous country (Table 2.2).
China’s population is currently greater than that of some
entire world regions (Global Population Profile 2002). By
2050, world population is estimated to reach 7 900 to
10 900 million, when stabilization of the Earth’s popula-
tion is likely to take place. Whether or not world popu-
lation falls within that range by this middle of this cen-
tury—rather than exceeding it—will depend upon many
of the choices and commitments that people make in the
coming years (UNFPA 2001).
The size of any population changes as a result of fluc-
tuations in three fundamental factors: birth rate, death
rate, and immigration or emigration. When any or all of
these factors deviate from zero, the size of thepopulation will change (Global Population
Profile 2002). The primary driving force of
population change, whether in an individual
country or for the entire world, is change in
birth and death rates.
World population is growing more slowly
than was expected (Figure 2.1) as a result of
aid, family planning programs, and educa-
tional and economic programs directed at
women. People are also healthier and living
longer than they did in the past; average life
expectancy has increased while crude birthrate and death rate are following a downward
trend (Tables 2.3, 2.4, 2.5 and 2.6).
Most future population growth is likely to
be in countries that have relatively large num-
bers of young people and where large families
are still the norm. Furthermore, declining mortality and
increased longevity have resulted in, and will continue to
lead to, the expansion of older populations. Worldwide,
2.1 World Population
Table 2.1 – World population for given points in timeSource: ESA 2003
Year Population
1970 3 692 492 000
1975 4 068 109 000
1980 4 434 682 000
1985 4 830 979 000
1990 5 263 593 000
1995 5 674 380 000
2000 6 070 581 000
2005 6 453 628 000
2010 6 830 283 000
Source: Global Population Profile 2002
1804
1922
1959
1974
1987
1999
2013
2028
2048
1800 1850 1900 1950 2000 20500
1
2
3
4
5
6
7
8
9
10Population in billions Total world population
118 years
37 years
15
years
13 years
12 years
14 years
15 years
20 years
Source: United Nations (1995b); U.S. Census Bureau, International Programs Center, International Data Base and unpublished tables.
Figure 2.1: Time to successive billions in world population: 1800-2050.
Credit: Khin Aye Myat/UNEP/Topfoto
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the average life expectancy in 1950 was 46 years; in 2050,
it is projected to be 76 years (Hunter 2001).
While an increase in life expectancy is a positive de-
velopment, it presents a new set of challenges. In Europe,
for example, where women give birth to an average of 1.4
children, governments are concerned that there will be
too few workers in future years to support the growing
number of retirees in the population. An aging popula-
tion strains a nation’s social security system and pension
plans, and puts pressure on health budgets because of higher health care costs for the elderly. Some govern-
ments are also concerned that a shortage of working-age
individuals may lead to increased immigration, and that a
decline in population may signal a weakening of a coun-
try’s political and economic clout (Ashford 2004).
One of the main reasons that world population has
grown so rapidly over the last 200 years is that mortal-
ity rates have declined faster than fertility
rates. Improved sanitation, health care,
medicine, shelter, and nutrition have all
led to dramatic increases in life expectancy.
Fertility rates, on the other hand, declined
more recently than mortality rates did
(UNEP 1999).
There is a striking paradox in global
population trends: for more than two de-
cades, many developing countries have ex-
perienced a rapid decline in fertility while
fertility rates in most highly developed na-
tions have remained very low (Figures 2.3
and 2.4). Yet in the coming years, a massive
increase of the world population is almost
certain (Heilig 1996).
The Demographic Transition Model
(Figure 2.2) shows how a country’s popula-
tion can change as the country develops.
However, this model does not take into
account migration. Worldwide, migration
of people out of rural areas is accelerating,
making internal and international
Table 2.3 – Median age for given points
in time Source: ESA 2003.
Year Median age
1970 21.7
1975 22.01980 22.7
1985 23.4
1990 24.3
1995 25.3
2000 26.4
2005 27.4
2010 28.4
Table 2.5 – Crude birth rate per 1 000 population - Medium variant Source: ESA 2003.
Period Crude birth rate
1970-1975 30.9
1975-1980 28.11980-1985 27.4
1985-1990 26.8
1990-1995 24.5
1995-2000 22.7
2000-2005 21.3
2005-2010 20.4
Table 2.6 – Crude death rate per 1 000 population - Medium variant Source: ESA 2003.
Period Crude death rate
1970-1975 11.6
1975-1980 10.91980-1985 10.3
1985-1990 9.7
1990-1995 9.5
1995-2000 9.2
2000-2005 9.1
2005-2010 9.0
Table 2.4 – Average life expectancy at birth - Medium
variant Source: ESA 2003.
Period Both sexes Male Female combined
1970-1975 58.0 56.5 59.5
1975-1980 59.8 58.1 61.5
1980-1985 61.3 59.4 63.2
1985-1990 62.9 60.9 64.8
1990-1995 63.8 61.7 65.9
1995-2000 64.6 62.5 66.9
2000-2005 65.4 63.3 67.6
2005-2010 66.3 64.2 68.4
Table 2.2 – The Top Ten Most Populous Countries: 1950, 2002, 2050
1950 2002 2050
1. China 1. China 1. India
2. India 2. India 2. China
3. United States 3. United States 3. United States
4. Russia 4. Indonesia 4. Indonesia
5. Japan 5. Brazil 5. Nigeria
6. Indonesia 6. Pakistan 6. Bangladesh
7. Germany 7. Russia 7. Pakistan
8. Brazil 8. Bangladesh 8. Brazil
9. United Kingdom 9. Nigeria 9. Congo (Kinshasa)
10. Italy 10. Japan 10. Mexico
Source: U.S. Census Bureau, International Programs Center, International Data Base are unpublished tables.
Credit: Ed Simpson/UNEP/PhotoSpin
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18
migration potentially one of the most
important development and policy issues
of this century. The migration of labor
geographically, out of rural areas, and
occupationally, out of farm jobs, is one of
the most pervasive features of agricultural
transformations and economic growth. Yet
in a world of complete and well-function-
ing markets, there is little or no economic
rationale for policies to reduce migration;
the movement of labor out of agriculture is
both a quintessential feature of agricultural
transformations and a prerequisite for
efficient and balanced economic growth
(Taylor and Martin 2002).
Clearly, human numbers cannot con-
tinue to increase indefi nitely. The more
people there are and the longer they live,
the more competition there will be for the
Earth’s limited resources. Unless all na-
tions adopt more sustainable methods of
Figure 2.2: The Demographic Transition Model shows how population growth occursnaturally in four stages. Stage 1: Birth rate and death rate are high, limiting both therate of increase and total population. Stage 2: Birth rate remains relatively high but death rate begins to fall, causing the population to grow rapidly. Stage 3: Declining birth rate and low death rate maintain continued population growth. Stage 4: Bothbirth rate and death rate are low, slowing population growth, but leaving a large total population. Source: http://www.geography.learnontheinternet.co.uk/topics/growth
6.7
5.1 5.1
2.6
5.0
2.62.02.0 2.2 1.4
1970 2004
Africa Asia Latin America& Caribbean
North America
Europe
Figure 2.3: Childbearing trends in major worldregions, 1970 and 2004
Total fertility rate (children per woman)
Source: UN Population Division. World Population Prospects: The 2002 Revision (1970 data), and C. Haub, 2004 World Population Data Sheet (2004 data).
Figure 2.4: Different patterns of fertility decline, 1970-2000
0
1
2
34
5
6
7
1970 1975 1980 1985 1990 1995 2000
BangladeshIndia
Argentina
Thailand
Children per woman
Sources: Registrar General of India; Instituto Nacional de Estadística (Argen- tina); United Nations Population Division; Institute of Population a nd Social Research, Mahidol University, Thailand; Demographic and Health Surveys; and Population Reference Bureau estimates.
Credit: Unknown/UNEP/Topfoto
5,000 and higher
No data
10 - 49
1 - 9
50 - 99
100 - 199
200 - 499
500 - 999
1,000 - 1,999
2,000 - 4,999
, nh i h r
t , ,
, ,
Population Density persons per squar
Population Density Map
Source: http://beta.sedac.ciesin.columbia.edu/
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production and consumption, the planet’s
carrying capacity will be exceeded (UNEP
1999).
Natural resources are already severely
limited, and there is emerging evidence
that natural forces are already starting
to control human population numbers
through malnutrition and disease (Pimen-
tel et al. 1999).
The environmental challenges that peo-
ple now face and most likely will continue
to face in the future would be less difficult
if world population were growing very
slowly or not at all. The number of people
on the Earth and the rate at which that
number increases (Table 2.7) dramatically
impact the availability of water, soil, ar-
able land, minerals, fuels, and many other
natural resources worldwide. Access to and
use of family planning services can help
lower fertility rates and delay child-bearing
Case Study: Monitoring Rapid UrbanExpansion of Tehran, Iran
1975 and 2000
Tehran is located at the foot of the AlborzMountains. The city occupies the northern part of the alluvial Tehran Plain, sloping from the
mountains to the flat Great Salt Desert. The ur-ban area is bounded by mountains to the northand east making it difficult to differentiate theurban area from the mountainous and desert area that surrounds Tehran.
The population of Tehran has grown three-fold since 1970 when the population was threemillion. In 1987, the city had grown to more
than seven million people and covered an areaof 575 km2 (230 square miles). Today the city has nine million residents.
The rapid expansion of Tehran, as well as itssharp population growth in recent decades, hashad many adverse impacts on the environment.
Air and water pollution are major problems inthe city. Urban areas are replacing farms and
water resources. A major concern is its locationon a recognized zone of active faulting with amodest to high seismic risk. Recent planningand construction techniques are designed toimprove the resistance to a major earthquakethat could threaten the city.
Credit: Saman Salari Sharif/UNEP/UNEP-GRID Geneva
The map portrays the boundaries of urban areas with defined populations of 5 000 persons or more. Source: Modified from http://beta.sedac.ciesin.columbia.edu/gpw/global.jsp
Global Urban Extent Map
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20
years, years, thereby helping to slow popu-
lation growth. Comprehensive population
policies are an essential element in a world
development strategy that combines access
to reproductive health services, education
and economic opportunities, improved
energy and natural resource technologies,
and more reasonable models of consump-
tion and what constitutes “the good life.”
Such a strategy has the potential to bring
humanity into an enduring balance with
the environment and the natural resources
upon which people will always depend
(Population Fact Sheet 2000).
In addition to the overall global increas-es in population, the geographic distri-
bution of human population underwent
massive changes during the 20th century
(Figure 2.5). For example, between 1900
and 1990, the population of northern
South America increased by 214 million, or
681 per cent, compared to the global aver-
age population increase of 3 700 million,
or 236 per cent (Ramankutty and
Olejniczak 2002).
Population growth around Lake Victoria,Kenya, is significantly higher than in the rest of Africa because of the wealth of naturalresources and economic benefits the lake re-gion offers. Note the increase in populationin a 100-km (62 miles) buffer zone aroundLake Victoria between 1960 and 2000. Dur-ing each decade, population growth withinthis zone outpaced the continental average.Source: UNEP/GRID- Sioux Falls
Lake Victoria, Kenya
0 – 0.5
0.5 – 10
10 – 100
100 – 250
250 – 500
500 – 1000
greater than 1000
Population density(people per sq km)
Table 2.7 – World Vital Events Per Time Unit: 2004(Figures may not add to totals due to rounding)
Natural Population Time unit Births Death Increase
Year 29 358 036 56 150 533 73 207 503
Month 10 779 836 4 679 211 6 100 625
Day 353 437 153 417 200 021
Hour 14 727 6 392 8 334
Minute 245 107 139Second 4.1 1.8 2.3
Source: http://www.census.gov/cgi-bin/ipc/pcwe
Figure 2.5: Population change in the 20th century Source: http://www.bioone.org/pdfserv/i0044-7447-031-03-0251.pdf
Credit: Ed Simpson/UNEP/PhotoSpin
Water
Low (<25)
Medium (25–100)
High (>100)
Population Density (people/km2)
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2.2 CultureCulture encompasses the customary beliefs, social forms,
and material traits of a racial, religious, or social group.
Culture includes the set of values and institutions that
enable a society to develop and maintain its identity.
Cultural signatures differ around the globe and often
hold to very different ideals and ideas, such as the role
of economics as an integrating system of values or the
importance of technology and technological change as
springboards for human progress. Different cultures also
differ in their concepts of justice and fairness and their
beliefs about the relationship between people and the
natural and spiritual world (UNEP 2002a).
Many of these differences are disappearing as cultures
worldwide become increasingly homogeneous. Major
steps in this direction occurred in the fifteenth century
with European exploration and colonization and in the
nineteenth century with the Industrial Revolution. In
recent decades the creation of the European Union and
spread of globalization has lowered many international
barriers and concurrently impacted cultural diversity.
Following the collapse of the Eastern Bloc in 1989, capi-
talism became more pervasive and less nationally limited.
Globally, world-spanning communication networks,
and inexpensive air travel have reduced the costs of
cross-cultural connections of all kinds, boosting televi-
sion, tourism, and emigration to new levels. Global
financial integration has proceeded at a furious pace,
along with the international fl ow of goods and services
as countries become increasingly dependent on one
Credit: Unknown/UNEP/Bigfoto
Source: Terralingua, UNESCO, and WWF 2003
The World’s Biocultural Diversity. People, Languages and Ecosystems
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22
another for food and basic commodities
(Wilk 2000). Explosive development of
electronic media has intensified cultural
homogenization by promoting the ideals
of a handful of cultures over those of many
others (Gary and Rubino 2001). The tech-
nological expansion of the media, in par-
ticular the Internet, is bringing different
cultures and civilisations ever closer; while
this increases the possibility of dialogue, it
can also be perceived as a threat to cultur-
al diversity, In short, current globalization
of trade and mass culture, together with
unprecedented demand for consumer
goods, has significantly impacted indig-
enous cultures around the globe.
Every civilisation and culture is uniqu
and irreplaceable, in that all cultures
and civilisations are part of the common
legacy of humankind (UN 2000). In many
parts of the world, English has become
the dominant language, having displaced
native tongues and dialects. According to
a recent UNEP report (UNEP, 2001) there
were 5 000 to 7 000 spoken languages in
the world with 4 000 to 5 000 of these clas-
sified as indigenous. Thirty-two per cent
Source: http://highered.mcgraw-hill.com/site/dl/free/007248179x/35299/map12.pdf
Languages of the World
Source: Modified from http://www.neiu.edu/~ejhowens/104/6/cultur.gif
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of the world’s spoken languages are found in Asia, 30 per cent
in Africa, 19 per cent in the Pacific, 15 per cent in the Ameri-
cas, and three per cent in Europe. More than 2 500 languagesare in danger of immediate extinction, while 234 have already
died out and many more were losing their connection to the
modern world. Some researchers estimate that over the next
century 90 per cent of the world’s languages will have become
extinct or virtually extinct. More than 350 languages already
have fewer than 50 speakers (Table 2.8). Such rare languages
are more likely to decline or disappear than those that are
more common (Sutherland 2003). The disappearance of any
language represents an irreparable loss for the heritage of all
humankind (Wurm 1970). The loss has been likened to the
extinction of a species—an unfortunate cultural analog to the
alarming events now occuring in the biological world. In fact,
Table 2.8 – The most common languages in the world
Approximate number Countries with of native speakers substantial numbers
Language (in the year 2000) of native speakers
1. Mandarin Chinese 874 000 000 162. Hindi (India) 366 000 000 173. English 341 000 000 1044. Spanish 322-358 000 000 435. Bengali 207 000 000 9
(India and Bangladesh)6. Portuguese 176 000 000 33
7. Russian 167 000 000 308. Japanese 125 000 000 269. German (standard) 100 000 000 40
10. Korean 78 000 000 31 11. French 77 000 000 53 12. Wu Chinese 77 000 000 1 13. Javanese 75 000 000 4 14. Yue Chinese 71 000 000 20 15. Telegu (India) 69 000 000 7
Note: These statistics are only rough approximations in most cases.(Source: The World Almanac and Book of Facts, 2003)
Credit: Unknown/UNEP/Bigfoto
Source: http://highered.mcgraw-hill.com/site/dl/free/007248179x/35299/map11.pdf
Religions of the World
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24
the number of “living” languages spoken
on the Earth is dwindling faster than the
planet’s biodiversity.
Culture is an aspect and a means of
development. Much has been said about
the expansion of Western culture to the
detriment of others. It is clear that many individuals aspire to Western lifestyles,
while others associate Western cultural
values with selfish individualism and exces-
sive consumption. The spread of Western
culture is both a cause and an effect of
economic globalization, aided by the
far-reaching penetration of information
technologies and electronic media. At the
same time, there have been nationalist and
religious reactions against that culture,
sometimes resulting in terrorist activities
and in open warfare within or between na-
tions (UNEP 2002a).
The World has some 6 000 communi-
ties. The international migration rate is
growing every year and the number of mi-
grants has doubled since the 1970s. While
the reasons for migration vary, it is safe to
say that we live in an increasingly heteroge-
neous society. Difference naturally leads to
diversity of vision, values, beliefs, practices
and expression, which all deserve equal re-
spect and dignity (UNESCO 2003). While
highlighting the role of culture in develop-
ment, there is also a need to emphasize
the role of culture in promoting peace
(UNESCO n.d).
Just as biodiversity enriches our natural
environment and is essential for its pro-
tection, cultural diversity is a treasure of
humanity and a prerequisite for human
development (UN 2000). Cultural Diversity
presupposes respect of fundamental
freedoms, namely freedom of thought,
conscience and religion, freedom of opin-
ion and expression, and freedom to par-
ticipate in the cultural life of one’s choice.
Cultural Diversity is not just a natural fact
that we need simply recognize and respect.
It is about plurality of knowledge, wisdom
and energy, all of which contribute to
improving and moving the World forward
(UNESCO n.d.).
Variety in all aspects of life has been
a source of wonder and celebration for
countless centuries, and the loss of that
variety is an unfortunate prospect (Gary
and Rubino 2001).
A natural wonder formed by natural processes, RainbowBridge (far left) straddles a tributary of the ColoradoRiver in southern Utah in the United States. Two con-temporary bridges, one from Sydney, Australia (left),and the other from London, England (below left), echothe natural form of Rainbow Bridge, but are the obviousbyproducts of modern culture.
Credit: Ed Simpson/UNEP/PhotoSpin
Credit: Unknown/UNEP/Bigfoto
Credit: Unknown/UNEP/ Bigfoto Credit: W.R. Hansen/UNEP/USGS
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2.3 Land Use andDegradationGrowing crops, clearing land, planting trees, draining a wetland—
these and many other activities fall into the broad category of land
use, or how people use land. Land-use intensity is the extent to
which land is used. It is an indication of the amount and degree of
development in an area, and a reflection of the effects generatedby that development (Planning Department 2001).
As a measure of activity, land-use intensity can range from very
low (for example, a pristine wilderness area) to intermediate (a
managed forest ecosystem) to very high (urban and industrial
settings) (Lebel and Steffen 1998). From a global change perspec-
tive (Figure 2.6), land-use intensity is an important characteristic
in assessing change and its impact (Berka et al. 1995). Land-use
intensity is determined by the spatial requirements of a land-use
activity, relationship to open space, requirements for infrastruc-
ture (transportation routes, water, sewer, electricity, and commu-
nications), and environmental impact. Parameters for measuring
land-use intensity typically include:• type of land-use activity, such as agriculture, grazing, wood
production, or residential, commercial or industrial usage,
• duration of use,
• number of people, animals, plants, structures, or machines
that occupy the land during a given period, and
• amount of land involved.
Figure 2.6: This series of illustrations depicts global land-use change, particularly the expansion of cropland and grazing land, between 1700 and 1990. Credit: Klein
Goldewijk, K., 2001. Source: NASA 2002, http://www.gsfc.nasa.gov/topstory/20020926landcover.
html
Credit: Andre Louzas/UNEP/Topfoto
tropical evergreen/deciduous forest
savanagrassland and steppe
open shrub land
temperate deciduous forest temperate needle-leaf evergreen forest
intensive agriculture marginal cropland used for grazingdesert
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26
Also important in assessing land-use
intensity is to examine the relative imper-
viousness of the landscape. Impervious
surfaces, such as paved roads, inhibit or
entirely block the absorption of water by
underlying soil (Forney et al. 2001). Once
paved or otherwise made impervious, land
is not easily reclaimed. As environmentalist
Rupert Cutler noted (Brown 2001),
“Asphalt is the land’s last crop.”
Land-use intensity trends are usually
expressed through changes in inputs,
management, or number of harvests over a
given period of time. Only changes within
the same land-use category and on the
same area (change of intensity)—as op-
posed to changes from one type of land
use to another (for example, forest to
cropland)—are taken into account when
assessing trends (van Lynden et al. n.d.;
FAO 2002).
The Agro-Ecological Zones (AEZ)
methodology (Figure 2.7) is a system devel-
oped by the Food and Agriculture Organi-
zation of the United Nations (FAO) with
the collaboration of the International Insti-
tute for Applied Systems Analysis (IIASA),
that enables rational land use planning on
the basis of an inventory of land resources
and evaluation of biophysical limitations
and potentials. This methodology utilizes
a land resources inventory to assess, for
specified management conditions and
levels of inputs, all feasible agricultural
land-use options and to quantify expected
production of cropping activities relevant
Figure 2.8: A satellite image reveals a typical “feather” or “fish-bone” pattern of deforestation in Brazil. The pattern followsthe construction of a new road through the rain forest. Roads provide easy access for mechanicized logging to clear cut for-est sections. Clear cut sections can then be turned into agricul-tural fields as roads provide easy access to local markets.Source: UNEP/GRID–Sioux Falls
B R A Z I L
R o n d ô n i a
Ariquemmes
São Joao
Joao Filipe
Rio Branco
São Cruz
Uru-Eu-Wau-Wau
Indigenous
Area
Pacaás Novos
National Park
Karitiana
ndigenous
Area
R i o
C a n
d e
ia
s
R i o J a m
a r
i
B R A Z I L
R o n d ô n i a
10
Kilometers
Ariquemmes
São Cruz
Figure 2.7: Conceptual framework of the Agro-Ecological Zones methodology
Source: FAO 2000, http://www.fao.org/ag/agl/agll/gaez/index.htm
19 Sep 2001
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in the specific agro-ecological context.
The characterization of land resources
includes components of climate, soils and
landform, which are basic for the supply of
water, energy, nutrients and physical sup-port to plants (FAO 2000).
Worldwide, the effect people are having
on the Earth is substantial and growing.
Satellite images reveal in startling detail
the signs of human impact on the land-
scape. From the herringbone patterns
of deforestation etched into once-undis-
turbed rain forests (Figure 2.8) to the
patchwork patterns of agricultural fields
and concrete splotches of urban sprawl,
the evidence that people have become a
powerful force capable of reshaping theEarth’s environment is everywhere.
Scientists estimate that between one-
third and one-half of the Earth’s land
surface has been transformed by human
activities (Figure 2.9) (Herring n.d.). The
activity that has had the greatest impact onthe global landscape is agriculture. Twelve
per cent of the world’s land surface—an
area equivalent to that of the South Ameri-
can continent—is under permanent
cultivation (Ramankutty and Foley 1999;
Devitt 2001).
Over the next 30 years, the annual rate
of growth in global crop production is ex-
pected to decrease. However, the Food and
Agriculture Organization of the United
Nations predicts that production will still
exceed demand, despite the world’s grow-ing population. By 2030, 75 per cent of the
projected global crop production will oc-
cur in developing countries, compared to
50 per cent in the early 1960s. Increases in
production will be achieved by improving
plant yields and through more intensiveland-use activities, including multi-crop-
ping or high-cropping intensities (UCS
2004). In light of these projections, contin-
ued support of agricultural research and
policies in developing countries is vital.
Nearly one-third of the world’s crop-
land—1 500 million hectares—has been
abandoned during the past 40 years
because erosion has made it unproductive
(Pimentel et al. 1995). Restoring soil lost
by erosion is a slow process; it takes rough-
ly 500 years for a mere 2.5 cm (1 inch)of soil to form under agricultural
Source: http://www.isric.nl/
Global Soil Degradation Ma p
Credit: Xintian Pan/UNEP/Topfoto
Source: http://www.isric.nl/
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28
conditions (Pimentel et al. 1996). Thus the
approach to replacing eroded agricultural
lands typically has been to clear more and
more areas of grassland or forest and con-
vert them to cropland. The ever-growingneed for agricultural land accounts for 60
to 80 per cent of the world’s deforestation
(Figure 2.9).
Despite such “replacement” strategies,
the amount of available cropland
worldwide has declined to 0.27 hectare
(0.67 acres) per person (Pimentel et al.
1996). It is possible to feed one adult on
a plant diet grown on about 0.2 hectares
(0.5 acres) of land (Knee 2003)—and
this land-per-person minimum is roughly
what will be available when worldpopulation reaches 8 000 million—but
only if crop yields now being achieved
in developed countries are achieved
worldwide. To do so requires that most
countries’ inputs of fertilizer, and probably
pesticides, rise to match those of North
America and Europe. Furthermore, any mechanization of crop production will
entail additional energy consumption.
Increased mechanization is likely given
the mass migration from rural areas to
cities currently underway on all continents.
While agriculture accounts for only about
two per cent of energy consumption in
North America and Europe, it accounts
for roughly ten per cent of energy
consumption in the rest of the world
(Knee 2003).
The shortage of cropland, together withfalling productivity, is a significant factor
contributing to global food shortages and
associated human malnutrition. Political
unrest, economic insecurity, and unequal
food distribution patterns also contribute
to food shortages worldwide (Pimentel et
al. 1996).
In addition to agriculture, the global
trend toward urbanization is another key
factor bringing change to the landscape.
Historically, forests and grasslands have
been converted to cropland. Increasingly,cropland is being converted to urban areas
(Ramankutty and Foley 1999; Devitt 2001).
Millions of hectares of cropland in the
industrial world have been paved to create
roads and parking lots. The average car re-
quires 0.07 hectares (0.17 acres) of paved
land for roads and parking space
(Brown 2001).
If farmers worldwide fail to meet the
challenge of increasing yields on existing
cropland, or they cannot access the tools
necessary to achieve increased yields, the
only alternative will be to clear the world’s
remaining forests and grasslands (Green
2001). Yet indications are that the world
does not have enough forests to fulfill all
the current and future demands being
placed on them (Nilsson 1996).
As natural forests are exhausted or
come under protection, the demand for
wood and wood products will be increas-
ingly satisfied by tree farms. Between 1980
and 1995, forest plantations in developed
countries increased from 45-60 million
hectares (111-147 million acres)to 80-100
million hectares (198-247 million acres).
Credit: Choosak Khemtai/UNEP/Topfoto
Figure 2.9: Human-induced land degradation (severe and very severe) as percentage of total land area
Source: World Atlas of Desertification (UNEP 1992)
30
25
20
15
10
5
0
A r e a ( m i l l i o n s q .
k m )
Total humaninduced landdegradation
Total land
Sub-Saharan Africa
North Africa
and NearEast
North Asia,east of Urals
Asia andPacific
Southand
Central America
North America
Europe
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In the developing world, the area in forest plantations doubled from roughly 40 mil-
lion to about 81 million hectares (99-200
million acres) over the same period. More
than 80 per cent of forest plantations in
the developing world are found in Asia,
where demand for paper and other wood
products continues to grow rapidly. For-
est plantations now cover more than 187
million hectares (462 million acres) world-
wide. That accounts for less than five
per cent of the Earth’s total forested area,
but 20 per cent of current global wood pro-duction (Larsen 2003).
Land Degradationand Desertification
By the beginning of the twenty-first cen-
tury, unprecedented global environmental
changes had reached sufficient propor-
tions to impinge upon human health—si-
multaneously and often interactively. These
changes include the processes of land
degradation and desertification (Menne
and Berollini 2000).
Land degradation is the decline in the
potential of land resources to meet hu-
man economic, social, and environmental
functions needs (Africa Mountain Forum
n.d.). Desertification is soil degradation in
arid regions, often to such an extent that
it is impossible to make the soil produc-
tive again (Table 2.9). Desertification is
the result of complex interactions between
unpredictable climatic variations and
unsustainable land use practices by com-munities who, in their struggle to survive,
overexploit agricultural, forest, and water
resources (CIDA 2001).
Over 3 600 million hectares (8 896 mil-
lion acres)—25 per cent of the Earth’s land
area—are affected by land degradation.
Desertification occurs to some extent on
30 per cent of irrigated lands, 47 per cent
of rain-fed agricultural lands, and 73 per
cent of rangelands (Figure 2.10). Annually,
an estimated 1.5 to 2.5 million hectares
(3.7 to 6 million acres) of irrigated land,3.5 to 4.0 million hectares (8.6 to 9 mil-
lion acres) of rain-fed agricultural land,
and about 35 million hectares (86 million
acres) of rangeland lose all or part of their
productivity due to land degradation pro-
cesses (Watson et al. 1998).
Desertification and drought are prob-
lems of global dimension that directly
affect more than 900 million people in
100 countries, some of which are among
the least developed nations in the world
(Watson et al. 1998). The consequences of desertification include (UNEP 2002a):
• reduction of the land’s natural resil-
ience to recover from climatic distur-
bances;
• reduction of soil productivity;
• damaged vegetation cover, such that
edible plants are easily replaced by
non-edible ones;
• increased downstream flooding, re-
duced water quality, sedimentation in
rivers and lakes, and siltation of reser-
voirs and navigation channels;
• aggravated health problems due to
wind-blown dust, including eye infec-
tions, respiratory illnesses, allergies,
and mental stress;
• undermined food production; and
• loss of livelihoods forcing affected
people to migrate.
Desertification results from misman-
agement of land and thus deals with two
interlocking, complex systems: the natural
Credit: Paiboon Patta/UNEP/Topfoto
Table 2.9 – Degree of soil degradation by subcontinental regions (per cent of total area)
None Light Moderate Strong Extreme
Africa 83 6 6 4 0.2
Asia 82 7 5 3 <0.1
Australiasia 88 11 0.5 0.2 <0.1
Europe 77 6 15 1 0.3
North America 93 1 5 1 0
South America 86 6 6 1 0
World:Per centage 85 6 7 2 <0.1Area (‘000 km2) 110 483 7 490 9 106 2 956 92
Source: World Atlas of Desertification (UNEP 1992)
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30
ecosystem and the human social system
(Eswaran et al. 1998). While much desert-
ification is attributed to poor land-use prac-
tices, hotter and drier conditions brought
about by potential global warming would
extend the area prone to desertification
northwards to encompass areas currently
not at risk. In addition, the rate of deserti-
fication would increase due to increases
in erosion, salinization, fire hazard, and
reductions in soil quality. As a result, the
process of desertification is likely to be-
come irreversible (Karas n.d.).
Worldwide, an estimated 6 to 27 million
hectares (15 to 67 million acres) of land
are lost each year to desertification. Seven-
ty per cent of the world’s dry land is de-
graded enough to be vulnerable to deserti-
fication (Anon 2002). The amount of land
susceptible to desertification (areas known
as tension zones) also is increasing. Cur-
rently, 7.1 million km2 (2.7 million square
miles) of land face low risk of human-in-
duced desertification, 8.6 million km2
(3.4 million square miles) are at moderate
risk, 15.6 million km2 (6.2 million square
miles) are at high risk, and 11.9 million
km2 (4.6 million square miles)are at very
high risk. Tension zones result from:
• excessive and continuous soil erosion
resulting from overuse and improper
use of lands, especially marginal and
sloping lands;
• nutrient depletion and/or soil acidi-
fication due to inadequate replenish-
ment of nutrients or soil pollution
from excessive use of organic and
inorganic agrichemicals;
• reduced water-holding capacity of
soils due to reduced soil volume and
reduced organic matter content, both
of which are a consequence of erosion
and reduced infiltration due to crust-
ing and compaction;
• salinization and water-logging from
over-irrigation without adequate
drainage; and
• unavailability of water stemming from
decreased supply of aquifers and
drainage bodies.
The following negative effects are high-
est in the tension zones (Eswaran et al.
1998):• systematic reduction in crop perfor-
mance, leading to failure in rain-fed
and irrigated systems;
• reduction in land cover and biomass
production in rangelands, with an
accompanying reduction in quality of
feed for livestock;
• reduction of available woody plants
for fuel and increased distances to
harvest them;
Credit: Rick Collins/UNEP/Topfoto
Figure 2.10: Soils are classified according to the proportions of different sized particles they contain. As seen in this figure, the largest percentage of world land area unsuitable for agriculture is land that is too dry. Source: FAO 2000, http://www.fao.org/desertification/default.asp?lang=en
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Case Study: Mt. Kenya–Diversity
in Ecosystems
Christian Lambrechts
Mount Kenya is located on
the equator 180 kilometres
north of Nairobi. It is a soli-
tary mountain of volcanic
origin with the base diam-
eter of about 120 km (75miles). Its broad cone shape
reaches an altitude of 5 199 m (17 057 ft) with
deeply incised U-shaped valleys in the upper
parts. Forest vegetation covers the major part
of the mountain, with a total area around
220 000 hectares (548 574 acres). The forests
are critical and invaluable national assets that
must be protected.
High diversity in ecosystems and species
The wide range in altitude clines—from 1 200
to 3 400 m (3 900 to 11 000 ft)—and rainfall
clines from—from 900 mm/year (35 in/year)in the north to 2 300 mm/year (91 in/year) in
the south-eastern slopes—contributes to the
highly diverse mosaic patterns of Mount Kenya
forests. Mount Kenya adds value to the na-
tion by providing tourism potential and local
cultural and economic benefits. It also pro-
vides important environmental services to the
nation such as a water catchment area of the
Tana River where 50 per cent of Kenya’s total
electricity output is generated.
Forest conservation initiative
Following a 1999 aerial survey, the entire forest
belt of Mount Kenya was gazetted as National
Reserve and placed under the management of
Kenya Wildlife Services in the year 2000. In
2002, a study was carried out to assess the effec-
tiveness of the new management practices put
in place in 2000. The study revealed significant
improvement in the state of conservation of
the forests.
This sub-scene of an ASTER satellite image showssand dunes covering an area roughly 12 km x 15 km(8 x 9 miles) in the Thar Desert of northwesternIndia and eastern Pakistan. The dunes here shift constantly, taking on new shapes. Approximately 800km (497 miles) long and 490 km (305 miles) wide,the Thar Desert is bounded on the south by a salt marsh known as the Rann of Kutch, and on the west by the Indus River plain. The desert’s terrain is pri-marily rolling sand hills, with scattered outcroppingsof shrub and rock. Source: NASA 2004, http://asterweb.jpl.nasa.gov/gallery/gallery.htm?name=Thar
Forest is shown in red on these images. Note the changes in forest cover in the boxes. Source: UNEP/GRID–Nairobi
• significant reduction in water from
overland flows or aquifers and a con-
comitant reduction in water quality;
• encroachment of sand and crop dam-
age by sand-blasting and wind erosion;
and
• increased gully and sheet erosion by
torrential rain.
Ultimately, desertification processes im-
pact about 2 600 million people, or 44 per
cent of the world’s population (Eswaran
et al. 1998).
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32
2.4 Ecoregions
and Ecosystems An ecosystem is an organic community of plants and an-
imals viewed within its physical environment (habitat);
the ecosystem results from the interaction between soil
and climate. It is a dynamic complex of plant, animal,
and microorganism communities and their non-livingenvironment interacting as a functional unit (UNEP-
WCMC 2003).
An ecoregion is a cartographical delineation of a
relatively large unit of land or water containing a geo-
graphically distinct assemblage of species, natural com-
munities, and environmental conditions. An ecoregion
is often defined by similarity of climate, landform, soil,
surface form, potential natural vegetation, hydrology,
and other ecologically relevant variables. Ecoregions
contain multiple landscapes with different spatial pat-
terns of ecosystems.
The ecoregion concept is one of the most important in landscape ecology, both for management and un-
derstanding (Hargrove and Hoffman 1999). Ecoregion
classifications are based on particular environmental
conditions and designed for specific purposes, and no
single set of ecoregions would be appropriate for all
potential uses (Wikipedia n.d.).
The environment of an ecoregion in terms of
climate, resource endowments, and socioeconomic
Credit: John R Jones/UNEP/Topfoto
Tropical rainforest
Tropical moist deciduous forest
Tropical dry forest
Tropical shrubland
Tropical desert
Tropical mountain
Polar
Water
No Data
Subtropical humid forest
Subtropical dry forest
Subtropical steppe
Subtropical desert
Subtropical mountain
Temperate oceanic forest
Temperate continental forest
Temperate steppe/prairie
Boreal coniferous forest
Boreal tundra woodland
Boreal mountain
Temperate desert
Source: USGS National Center for EROS
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conditions is homogeneous. Specific ad-
vantages of using an ecoregion approach
for planning and decision-making include:
• easier identification of production capa-
bilities and constraints;
• better targeting of prospectivetechnologies;
• improved assessment of responses to
new technologies; and
• wider adoption and larger impact of
research outputs (Saxena et al. 2001).
Trends
An increase in average global tempera-
ture has the potential to bring about
dramatic change in ecosystems. Some
species may be forced out of their habitats(possibly to extinction) because of chang-
ing conditions. Other species may flourish
and spread. Few, if any, terrestrial ecore-
gions on the Earth are expected to remain
unaffected by significant global warming.
Since 1970, there has been a 30
per cent decline in the world’s living
things and the downward trend is continu-
ing at one per cent or more per year (Col-
lins 2000; UNEP 1997). Table 2.10 shows
an increase in the number of endangered
and vulnerable species between the years
2000–2003. Modification of landscapes,
loss of native species, introduction of
exotic species, monoculture-focused agri-
culture, soil enhancement, irrigation, and
land degradation have all tended to “sim-
plify” ecosystems, leading to a reduction
in biodiversity. In aquatic environments,
eutrophication and habitat destruction
have had a similar effect (Tilman et al.
2001). As ecosystems become simpler, so
do ecoregions.
Ecoregion and ecosystem fragmenta-
tion also contributes to a decline in biodi-
versity and threatens many species. Glob-
ally, over half of the temperate broadleaf
and mixed forests and nearly one quarter
of the tropical rain forests have been frag-
mented or removed (Wade et al. 2003).
Table 2.10 – Loss of biodiversity from 2000 to 2003—expressed as changes in speciesnumbers—in animals and plants classified as critically endangered, endangered, and
vulnerable
Critically Endangered Endangered VulnerableGroup 2000 2002 2003 2000 2002 2003 2000 2002 2003
Mammals 180 181 184 340 339 337 610 617 609Birds 182 182 182 321 326 331 680 684 681
Reptiles 56 55 57 74 79 78 161 159 158
Amphibians 25 30 30 38 37 37 83 90 90
Fishes 156 157 162 144 143 144 452 442 444
Insects 45 46 46 118 118 118 392 393 389
Mollusks 222 222 250 237 236 243 479 481 474
Plants 1 014 1 046 1 276 1 266 1 291 1 634 3 311 3 377 3 864
Source: http://www.redlist.org/info/tables/table2.html
Credit: Philip De Mancz/UNEP/Topfoto
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Impacts
Simplification of ecosystems and ecore-
gions results in species extinctions and
a loss of natural resources (Tilman et al.
2001). Climate change and the way in
which ecological communities respond to
it have enormous conservation implica-
tions. These include developing awareness
of the transience of native ranges andplant associations and the significance of
population declines and increases, as well
as the need to develop targets and refer-
ences for restoration, and strategies for
dealing with global warming (Millar 2003).
For example, changes in the potential dis-
tribution of tree and shrub taxa in North
America in response to projected climate
change are expected to be far-reaching
and complex; growing ranges for various
species will shift not only northward and
upward in elevation but in all directions
(Shafer et al. 2001). Some models predict
that more than 80 per cent of the world’s
ecoregions will suffer extinctions as a
result of global warming (Malcolm et al.
2002). Ecoregions expected to be most
dramatically altered by climate change
include the boreal forests of the North-
ern Hemisphere, the fynbos of Southern
Africa, and the Terai-Duar savanna and
grasslands of northeastern India (Malcolm
et al. 2002).
Credit: Gary Wilson/UNEP/NRCS
Credit: Ron Levy/UNEP/Topfoto
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2.5 Biodiversity,
Invasive Species,
and
Protected AreasBiological diversity, or “biodiversity,” refers to the
variety of life on the Earth in all its forms. There
are three levels of biodiversity: biodiversity of a
landscape or ecosystem, species biodiversity, and
genetic biodiversity (IUCN, UNEP, and WWF
1991). These three levels are intimately connected.
For example, genetic diversity is often the key to
survival for a species, equipping it with the neces-
sary resources to adapt to changing environmental
conditions. Species diversity, in turn, is typically a
measure of ecosystem health (Rosenzweig 1999).
We have just begun to identify and fully un-
derstand the diverse living things that currently
inhabit the Earth. Scientists have discovered and
described roughly 1.75 million species to date.
That number is expected to increase substantially
when all marine organisms, arthropods, bacteria,
and viruses are eventually added to the list. Tragi-
cally, however, humans are destroying this great
diversity at an alarming rate. Rates of human-in-
duced species extinction are estimated to be 50 to
100 times the natural background rate; this couldCredit: Gyde Lund/UNEP
Credit: William M. Ciesla/UNEP/Invasive.org
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36
increase to 1 000 to 10 000 times the natu-
ral rate in the next 25 years (Lund et al.
2003; Pellew 1996).
Why are so many species becoming
extinct? Human activities over the last
three centuries have significantly trans-
formed the Earth’s environment, primarily
through the conversion of natural ecosys-
tems to agriculture (Ramankutty and Foley
1999). It is estimated that cropland ex-
panded from 3-4 million km2 (1.2-1.5 mil-
lion square miles) in 1700 to 15-18 million
km2 (5.8-6.9 million square miles) in 1990,
primarily at the expense of forests. At the
same time, grazing lands expanded from 5
million km2 (1.9 million square miles) in1700 to 31 million km2 (12 million square
miles) in 1990, largely via the conversion of
native grasslands (Goldewijk and Raman-
kutty 2001). In addition to agriculture-driv-
en landscape transformations, the move
to monoculture-based forms of agriculture
has contributed to declining biodiversity.
Wild plants and animals are a major
source of food. Billions of people still har-
vest wild or “bush” food around the world.
Between one-fifth and one-half of all food
consumed by poor people in developing
countries is gathered rather than culti-
vated. On a global scale, ocean fish caught
in the wild account for 16 per cent of the
human diet (Harrison and Pearce 2001).
Wild plants are also a major source of
medicine, and the loss of biological diver-
sity has serious implications in terms of
human health. Of the 150 most frequently
prescribed drugs, more than half are
derived from or patterned after chemical
compounds found in plants (Brehm 2003).
Moreover, plants are an important source
of fuel. Nearly 15 per cent of the world’s
energy is derived from the burning of plant
materials (De Leo and Levin 1997).
Worldwide, people eat only a small frac-
tion of the 70 000 plants known to be ed-
ible or to have edible parts (Wilson 1989).
But retaining biodiversity is still vital for
the food supply, since most food crops con-
stantly require an infusion of “wild” genes
to maintain their resistance to ever-evolv-ing pests (Harrison and Pearce 2001).
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Despite our dependence on biodi-
versity, it has been estimated that 27 000species are lost every year—roughly three
per hour. Other estimates put the number
much higher. The greatest loss of bio-
diversity is currently taking place in wet
tropical regions where rain forest ecosys-
tems are being altered dramatically. But
loss of biodiversity is also evident in drier
regions, due to desertification. Major con-
tributors to species extinctions and loss of
biodiversity worldwide include:
• human population growth;
• unsustainable patterns of consump-tion such as over-harvesting of plant
and animal resources;
• poor agricultural practices;
• increased production of wastes andpollutants;
• urban development; and
• international conflict (UNEP 2002b).
Loss of biodiversity occurs hand-in-
hand with habitat loss, and habitat loss is
generally greatest where human popula-
tion density is highest (Harrison 1997).
One type of habitat loss is fragmentation.
Fragmentation occurs where a once-con-
tinuous ecosystem is broken up into many
small, poorly connected patches of land,
which happens when blocks of trees are
removed from a forest. A change in land
cover typically accompanies fragmenta-
tion. Six categories of fragmentation havebeen identified (interior, perforated,
edge, transitional, patch, and undeter-
mined) depending on how a given area
of land is broken up (Riitters et al. 2000).
Fragmentation may be human-induced or
due to natural causes such as fire, floods,
or wind. Fragmentation may create more
diverse landscapes than were originally
present, and while it may destroy habitats
of some species, it can also create habitats
for others.
Left to right: Junipers near near Paulina, Oregon. Without natural fi res to control their spread pers can become invasive in rangelands (Credit: Gyde Lund/UNEP). Women herding goats (CUnknown/UNEP/Topfoto). Cattle grazing in a bog (Credit: Rubai Wang/UNEP/Topfoto). Kutaking over the land and trees in the southeastern United States (Credit: Gyde Lund/UNEP).
Photos left to right: A family of elephants in Africa (Credit : Gyde Lund/UNEP). A clear-ction of forest (Credit: Steven Poe/UNEP/Topfoto). Yellowstone National Park (Credit: GydUNEP). People often peel the loose bark of f birches for souvenirs. Danforth, ME USA (CredRandy Cyr/UNEP/Forestryimages.org).
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38
Invasive Species
Most plants and animals exist in places in
which they did not originate. They moved
or were introduced into new areas over
time. While rooted plants cannot them-
selves move from place to place, the dis-
persion of their seeds by wind, water, and
animals has enabled them to spread into
many new habitats.
An introduced species is one whose
existence in a given region is due to some
type of human activity. That activity may
enable the species to cross natural geo-
graphic barriers or it may transform condi-
tions in an area as to be in some way favor-
able to the species’ growth and spread.
Introduced species are also called alien, or
exotic, species.
Many introduced species have beenactively transported by people to new areas
for specific purposes and have played
important and beneficial roles in human
history. Most modern agricultural crops
were introduced into the regions they
now inhabit. For instance, corn (maize) is
thought to have originated in Mexico some
7 000 years ago. Today it is found world-
wide. Wheat probably originated in the
Middle East. Currently, wheat is grown on
more land area worldwide than any other
crop and is a close third to rice and corn in
total world production.
Many modern domesticated animals
were also new species introductions at
some point in their history. Modern do-
mestic cattle evolved from a single early
ancestor, the auroch. Cattle were domes-
ticated between 10 000 and 15 000 years
ago near the boundary of Europe and Asiaor Southwest Asia. Cattle are now widely
distributed throughout the world. The
total world cattle population in the late
Figure 2.11: The number and extent of the world’s protected lands increased significantly during the period from 1872 to 2003. The greatest increase hasoccurred over the past few decades. In 2003, the totalnumber of protected sites surpassed 100 000, whiletotal area increased to more than 18 million km2 (7million square miles). Source: Chape et al. 2003
100,000
80,000
60,000
40,000
20,000
01872 1902 1917 1932 1947 1952 1962 1977 1992 2003
0
2,000,000
4,000,000
6,000,000
8,000,000
10,000,000
12,000,000
14,000,000
16,000,000
18,000,000
Number of sites Area of Sites
Cumulative Growth in Protected Areas by 5 Year Increments:1872 – 2003
Case Study: Lake Maracaibo, Venezuela
Lake Maracaibo in northwestern Venezuela is
the largest natural lake in South America at
13 330 km2 (5 146 square miles). At its widest
point, it is more than 125 km (78 miles) wide.
The lake itself lies in the Maracaibo basin,
which is semi-arid in the north, but averages
over 1 200 mm (47 in) of annual rainfall in
the south. It has been suffering from a serious
problem of invasive duckweed, a tiny aquatic
plant that grows in freshwater. This first image
(left), taken by the Aqua MODIS satellite on
17 December 2003, shows the lake during the
winter months, when duckweed is absent from
the lake’s waters, and the silvery sunglint is ab-
sent. In summer the weed blooms. The true-co-
lour image from 26 June 2004 (middle) shows
strands of duckweed curling through the lake,
floating at the surface, or slightly submerged
in the brackish water. A closer look in August 2004 (right) reveals the stranglehold the duck-
weed has on port areas, especially along the
important oil shipping routes in the neck of
Lake Maracaibo. Fish and the fishing industry
suffer as thick green mats block photosynthesis
and alter fish habitats. The weed also adheres
to boats, affects cooling systems, and obstructs
travel. In September 2004, Venezuela’s Min-
istry of Environment and Natural Resources
reported that it had reduced the duckweed
area by 75 per cent, using duckweed harvesting
machines from the United States. The ministry is investigating using the harvested weed as
animal fodder.
Credit: (Left, right images) NASA; (middle) LPDAAC – USGS National Center for EROS
38
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1980s was estimated to be nearly 1.3 bil-
lion. Chickens—the world’s most abundant
domesticated bird—are generally believed
to have descended from jungle fowl in
Southeast Asia. They were subsequently
introduced into almost every country and
region of the world.
In stark contrast to such positive species
introductions are those where introduced
exotic species have become invasive. Scien-
tifically speaking, invasive species are those
organisms that are unwanted and have a
tendency to spread. Invasive species harm,
or have the potential to harm, a given
ecosystem or peoples’ health or economic
well-being (Clinton 1999). Historically,
some invasive exotic species have been
intentionally introduced into new settings;
the introduction of the common starling
into the United States and the rabbit into
Australia are two classic examples. Intro-
ductions of other invasive species haveoccurred by accident, such as that of zebra
mussels into the American Great Lakes as a
result of shipping activities.
Native or indigenous species are those
that occur naturally in an area or habitat.
Invasive species often out-compete and dis-
place native species because the invaders
have no natural enemies and can spread
easily and quickly. Both managed and
natural ecosystems throughout the world
are under siege from increasing numbers
of harmful invasive species. These include
disease organisms, agricultural weeds, and
destructive insects and small mammals that
threaten economic productivity, ecological
stability, and biodiversity. On a local scale,
such invasions decrease diversity of native
flora and fauna. Globally, they contribute
to making the biosphere more homoge-
neous and less resilient.
Natural biodiversity helps to maintain
ecological resilience in the face of varying
environmental conditions (Holling et al.
1995). Invasion by exotic species lessens
ecological resilience and can transform
ecosystems in unpredictable ways that may
have negative consequences for people.
This problem is growing in severity and
geographic extent as global trade and
international travel expand, as markets
are liberalized and deregulated, as ecosys-
tems are further altered and fragmented,and as global climate continues to change
(Brandt 2003; Dalmazzone 2000).
Invasions by alien species are set to
worsen in the next few decades if the
world continues to warm as most scientists
predict it will. Longer growing seasons
spawned by global warming may give
invasive weedy plants time to flower and
set seeds where previously they could only
spread asexually. This new-found ability
could allow the weeds to adapt to new
environments more quickly, and better
resist attack by insects. Higher levels of
carbon dioxide in the atmosphere may also
favor plants that can utilize extra carbon
dioxide and grow faster. One such example
is cheatgrass, an introduced species that
now dominates vast areas of the American
West (Holmes 1998). In other parts of the
world, invasive exotic plant species make
up 4 to 44 per cent of the total number of
species in ecosystems (Lövei 1997).
Invasive exotic species are one of the
most significant drivers of environmental
change worldwide. They also contribute
to social instability and economic hard-
ship, and place constraints on sustainable
development, economic growth, and en-
vironmental conservation. Worldwide, the
annual economic impact of invasive species
on agriculture, biodiversity, fisheries, for-
ests, and industry is enormous. The World
Conservation Union (IUCN) estimates that the global economic costs of invasive exotic
species are about US$400 billion annually
(UNEP 2002a). Alien invaders cost 140 bil-
lion dollars a year in the USA alone (Mc-
Grath 2005). Less easily measured costs
also include unemployment, impacts on
infrastructure, shortages of food and water,
environmental degradation, increases in
the rate and severity of natural disasters,
and human illness and death. Invasive ex-
otic species represent a growing problem,
and one that is here to stay—at least forthe foreseeable future (Brandt 2003).
Protected and Wilderness Areas
Wilderness areas are those areas of land
that are relatively untouched by human
activities. To qualify as wilderness, an area
must have 70 per cent or more of its origi-
nal vegetation intact, cover at least 10 000
km2 (3 861 square miles), and be inhab-
ited by fewer than five people per km2 (12
people per square mile).
Wilderness areas are major storehousesof biodiversity. They also provide critical
ecosystem services to the planet, including
watershed maintenance, pollination, and
carbon sequestration. Wilderness areas
currently cover nearly half the Earth’s ter-
restrial surface (Mittermeier et al. 2003).
While that represents a significant amount
of land area, however, most wilderness
areas are not protected, and are therefore
at risk.
Table 2.11 – Growth of protected areas of the world in 1994 and 2004 (in per cent)
Ratio 1994 2004
World 7.8 9.5
Developed Countries 11.3 14.1
Commonwealth Independent States (CIS) 2.8 3.0
CIS-ASIA 3.6 3.8
CIS-Europe 2.6 2.8
Developing 7.6 9.1
Northern Africa 3.5 3.9
Sub-Saharan Africa 8.1 8.3Latin America & the Caribbean 8.0 9.9
Eastern Asia 8.2 14.2
Southern Asia 4.5 5.1
South-eastern Asia 4.8 5.9
Western Asia 21.4 22.0
Oceania 1.0 1.1
Least Developed Countries (LDCs) 7.7 7.9
Landlocked Developing Countries (LLDCs) 8.4 9.6
Small Island Developing States (SIDs) 1.6 2.8
There is considerable variation in the total area protected between regions, ranging from 1.1 per cent inthe developing countries of Oceania to 22.0 per cent in Western Asia. The percentage coverage in both
Western and Eastern Asia (14.2 per cent) exceeds the coverage of all developed countries (14.1per cent) representing a significant commitment by these regions to conservation. However, the con-
straints imposed upon the data by the criterion for a date of establishment within the Millennium Devel-opment Goals (MDG) reporting period suggest that all figures should be treated cautiously.
Source: UNEP-WCMC 2005
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40
One of the most effective means for
conserving wilderness is through the de-
velopment of protected areas. A protected
area is an area of land (or water) especially
dedicated to the protection and mainte-
nance of biological diversity, along with
natural and associated cultural resources,
that is managed through legal or other
effective means (IUCN 1994). Protected
areas are managed for a wide variety of
purposes, including:
• scientific research;
• wilderness protection and preservation
of species and ecosystems;
• maintenance of environmental
services;
• protection of specific natural and
cultural features;
• tourism and recreation;
• education;
• sustainable use of resources from
natural ecosystems; and
• maintenance of cultural and tradition-
al attributes (Green and Paine 1997).
The 2003 United Nations List of Pro-
tected Areas—compiled by UNEP and
the IUCN and released during the Fifth
World Parks Congress in Durban, South
Africa—reveals that there are now 102 102protected areas, together representing a
total land area roughly equivalent to China
and Canada combined, or more than 12
per cent of the Earth’s surface (Chape et
al. 2003). That total exceeds the ten
per cent called for in the Caracas Action
Plan formulated at the Fourth World Parks
Congress held in 1992 in Caracas, Venezu-
ela. Between 10 and 30 per cent of some of
the planet’s vital natural features, such as
Amazonian rain forests and tropical savan-
nah grasslands, are classified as protected
areas. However, ecoregional and habitat
representation remains uneven.
Currently, almost half of the world’s
protected areas are found in regions where
agriculture and logging are primary land-
use strategies. All indications are that food
Source: www.conservation.org
World Environmental Hotspots as identified by Conservation International.
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and timber production will need to in-
crease in coming decades to keep up with
population growth and increasing demand
for wood and wood products. Thus, estab-
lishing additional protected areas, while
helping to preserve biological diversity, will
take land out of production and put more
stress on lands elsewhere (Sohngen et al.
1999). Balancing the need to protect wild
species and conserve habitat while at the
same time increasing agricultural and tim-
ber production represents a tremendous
challenge (McNeely and Scherr 2001).
Of the world’s protected areas, the vast
majority—91.3 per cent—are found in ter-
restrial ecosystems. Fewer than ten
per cent of the world’s lakes and less than
0.5 per cent of the world’s seas and oceans
lie within protected areas (SBSTTA 2003).
Recognizing that the world’s marine en-
vironment remains largely unprotected,
the Fifth World Parks Congress put forth
the Durban Action Plan. The Plan calls forthe establishment of at least 20-30 per cent
marine protected areas worldwide by 2012.
The Plan also calls for the conservation of
all globally threatened or endangered spe-
cies by 2010.
In the coming years, further develop-
ment of global networks of protected areas
will need to focus on four areas (Green
and Paine 1997):
• consolidating existing networks by ad-
dressing major gaps;
• physically linking protected areas to
one another so they function more ef-
fectively as networks;
• expanding networks by forming or
strengthening links with other sectors,
notably the private sector;
• and improving the effectiveness with
which protected areas are managed.
Protected areas are often considered a
kind of sacrifice, a financial burden rather
than an asset. Yet establishing, maintain-
ing, and expanding protected areas is a
fundamental approach to safe-guarding
the environment and conserving
biological diversity.
Protected areas are also important in
other respects, such as helping to maintainfreshwater resources. Protected areas may
also hold the cures to some of the world’s
most devastating diseases in the form of
unique chemical compounds and as-yet-un-
discovered genetic material.
A recent analysis published by Con-
servation International identified nine
additional sites as areas of extraordinarily
high biological diversity, popularly known
as hotspots, taking the count of hotspots to
34. These 34 regions worldwide are where
75 per cent of the planet’s most threatened
mammals, birds, and amphibians survive.
In these 34 hotspots, estimated 50 per cent
of all vascular plants and 42 per cent of
terrestrial vertebrates exist. Therefore it is
critical to protect and preserve these areas
(Conservation International 2005).
Credit: Christian Lambrechts/UNEP
Credit: Harriett O’Mahony/UNEP/Topfoto
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42
Case Study: Kameng and Sonitpur
Elephant Reserves,
Arunachal Pradesh, India
S. P. S. Kushwaha and Rabul Hazarika
The Kameng and Sonitpur Elephant Re-
serves in northeastern India are comprised of
transborder subtropical evergreen to tropical
moist deciduous forests of Arunachal Pradesh
andAssam. The reserves are facing deforesta-
tion and habitat loss in recent years. This study
attempts to investigate the loss of habitat in
these reserves using temporal satellite imagery
of periods 1994, 1999 and 2002. The on-screen
visual interpretation of the three-period imag-
ery revealed alarming and continuous habitat
loss from 1994 to 2002. The overall habitat loss
was found to be 344 km2 (133 square miles) be-
tween 1994 and 2002. The average annual rate
of deforestation worked out to be 1.38
per cent, which is much bigger than the na-
tional average. The rate of deforestation was
highest between 1999 and 2002. The study indi-cated that at this rate much of the forests in the
study area would be depleted within the next
few years. It also showed that moist deciduous
forests, which possess the highest biodiversity
in Assam, are facing maximum deforestation.
High deforestation has resulted in high man-
elephant conflicts.
Habitat loss (1999–2002)Habitat loss (1994–1999)
Habitat loss (1994–2002)
Credit: Dr. Bibhab Talukdar
Map of Study Area
Sonitpur
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2.6 Energy
Consumption
and Resource
ExtractionEnergy is measured by its capacity to do work
(potential energy) or the conversion of this
capacity to motion (kinetic energy). Most of the
world’s convertible energy comes from fossil fu-
els that are burned to produce heat that is then
converted to mechanical energy or other means
in order to accomplish tasks (EIA 2004a).
Energy is essential for the fulfillment of many
basic human needs, such as generating electric-
ity, heating and cooling living spaces, cooking
food, forging steel, and powering engines for
many forms of transportation (Harrison andPearce 2001). Energy use is closely tied to hu-
man health and well-being. Worldwide, roughly
2 000 million people do not have access to elec-
tricity. Countries in which energy use is low tend
to have high infant mortality rates, low literacy
rates, and low life expectancies. It is through
the utilization of convertible energy sources that
the modern world has transcended its agrarian
roots and fostered the energy-driven societies
that characterize it today. Generating the power
to sustain these societies has entailed extract-
ing massive amounts of natural resources fromthe planet. Extraction is the process of obtain-
Credit: Darren Defner/UNEP/Topfoto
Credit: NOAA/UNEP/NASA Nightlight Map of the World
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44
ing a useful substance from a raw material
(NCR&LB 2003). Such raw materials may
include fossil fuels, metals, minerals, water,
and biomass, including animals and raw
materials from plants and crops
(EEA 2001).
Resources can be divided into those that
are renewable, such as plant and animal
material, and those that are not, including
coal, oil, and minerals. The Earth has a
finite supply of non-renewable resources.
Even renewable resources, however, are
exhaustible if they are used faster than they
can be replenished.
Total world energy consumption has
risen almost 70 per cent since 1971 (WRI
1998). It is expected to increase by 58 per
cent between 2001 and 2025, from 404
quadrillion British thermal units (Btu) in
2001 to 640 quadrillion Btu in 2025 (EIA
2003; EIA 2004b). While a slow, steady in-
crease in energy consumption is expected
in industrialized nations, where most en-
ergy use currently takes place, a meteoric
increase in consumption is anticipated in
the developing world during that period
(Tilford 2000).
The tempo at which energy resources
are being used to fuel modern societies
is rapidly depleting supplies of non-re-
newable resources and far exceeding the
rate at which renewable resources can be
naturally renewed (Ernst 2002). In many
least–developed countries, for instance,
burning biomass in the form of wood
(largely a non-renewable resource) gener-
ates 70 to 90 per cent of the energy needed
and disregard for the fate of non-renew-
able resources is prevalent. In the United
States, for example, 72 per cent of the
country’s electricity is generated using non-
renewable resources. Only about 10 per
cent comes from renewable resources, with
nuclear power providing the rest.
Currently, 85 per cent of world energy
consumption comes from the burning of
fossil fuels—oil, coal, and natural gas (BP
2003). Although no immediate shortages
of these non-renewable energy resources
exist, supplies are finite and will not last
forever. What took millions of years to
Global Natural Resources
Affluent countries consume vast quantities of global natural resources, but contribute
proportionately less to the extraction of many raw materials. This imbalance is due, in
part, to domestic attitudes and policies intended to protect the environment. Ironically,
developed nations are often better equipped to extract resources in an environmentally
prudent manner than the major suppliers. Thus, although citizens of affluent countries
may imagine that preservationist domestic policies are conserving resources and
protecting nature, heavy consumption rates necessitate resource extraction elsewhere and
oftentimes with weak environmental oversight. A major consequence of this “illusion of
natural resource preservation” is greater global environmental degradation than would
arise if consumption were reduced and a larger portion of production was shared by
affluent countries. Clearly, environmental policy needs to consider the global distributionand consequences of natural resource extraction (Berlik et al. 2002).
Case Study: Blackout inUnited States and Canada
14 August 2003
On 14 August 2003, parts of the northeast-
ern United States and southeastern Canada
experienced widespread power blackouts.
Among the major urban agglomerations af-
fected by the electrical power outage were
the cities of New York City, Albany, and Buf-
falo in New York, Cleveland and Columbus
in Ohio, Detroit in Michigan, and Ottawa
and Toronto in Ontario, Canada. Other
U.S. states, including New Jersey, Vermont,
Pennsylvania, Connecticut, and Massa-
chusetts, were also affected. The blackout resulted in the shutting down of nuclear
power plants in New York and Ohio, and
air traffic was slowed as flights into affected
airports were halted. Approximately 50
million people were affected by the outage.
The change in the nighttime city lights is
apparent in this pair of Defense Meteoro-
logical Satellite Program (DMSP) satellite
images. The top image was acquired on 14
August, about 20 hours before the black-
out, and the bottom image shows the same
area on 15 August, roughly seven hours
after the blackout. In the bottom scene,notice how the lights in Detroit, Cleveland,
Columbus, Toronto, and Ottowa are either
missing or visibly reduced. Previous major
blackouts include the 9 November 1965
outage caused by a faulty relay at a power
plant in Ontario, which affected a large
swath of land stretching from Toronto to
New York. Another one followed on 14
July 1977, the result of a lightning strike,
affecting New York City. The power supply
in nine western states was also affected in
August 1996 as a result of a high demand
for electricity, a heat wave, and sagging
electrical power lines.
Source: NASA 2002, http://earthobservatory.nasa.gov/ NaturalHazards/natural_hazards_v2.php3?img_id=11628; GlobalSecurity.org 2003, http://www.globalsecurity.org/eye/ blackout_2003.htm
Credit Image courtesy Chris Elvidge, U.S. Air Force http://earthobservatory.nasa.gov/NaturalHazards/Archive/Aug2003/NE_US_OLS2003227_lrg.jpg
Credit: Jon P Bonetti /UNEP/Topfoto
15 August 2003 after power failure
14 August 2003 before power failure
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Case Study: SWERA, the Solar and WindEnergy Resource Assessment
The Solar and Wind Energy Resource Assessment
(SWERA)—co-financed by the Global Environ-
ment Facility (GEF)—is a project to assist 13 devel-
oping countries identify optimal locations for po-
tential solar and wind energy production. SWERA
assists by creating a global archive of information
gathered through a network of international and
national agencies. These agencies collect and
analyse data on solar and wind energy resources,
energy demand, and electrification. Using inputs
derived from satellite and surface observations,
SWERA partners model wind and solar energy re-
source potential and produce maps of wind power
density and monthly average and daily total solar
radiation of a given area. This information can
then be used to facilitate investments and create
policies in the participating countries for develop-
ing solar and wind energy.
Source: UNEP/GRID–Sioux Falls
Credit: NCAT/UNEP/NREL
Credit: Energy Northwest/UNEP/NREL
Credit: NREL
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46
produce will be consumed in the time
frame of a century or two (Hawken 1994;
Tilford 2000).
This rapid, large-scale consumption of a
fuel source that took millennia to produce
has generated unforeseen complications,
several with global implications. Burning
fossil fuels produces atmospheric pollutants
such as oxides of sulfur and nitrogen and
unburned hydrocarbons. Fossil fuel com-
bustion also adds one of the most prevalent
greenhouse gases—carbon dioxide—to the
atmosphere. As a result, world energy use
has emerged at the center of the climate
change debate. World carbon dioxide emis-
sions are projected to rise from
23 900 million metric tonnes in 2001 to
27 700 million metric tonnes in 2010 and
37 100 million metric tonnes in 2025 (EIA
2004b). The Earth’s atmosphere and bio-
sphere will not remain unchanged by the
combustion of such enormous amounts of
these fuels. The relatively sudden release of massive amounts of carbon has the poten-
tial not only to disrupt the Earth’s heat
balance and climate, but other parts of
the global carbon cycle as well, and in
unpredictable ways.
The Earth cannot sustain existing levels
of resource consumption. Furthermore,
resource extraction methods are often
environmentally destructive. The impact
of environmental degradation hits those
who are poorest the hardest. Many of the
world’s energy sources and other naturalresources come from developing countries.
Extracting and harvesting these resources
can result in air, soil, and water pollution.
It also generates waste; the amount of waste
associated with extracting minerals, for
instance, can be enormous. Disposing of
wastes in environmentally friendly ways is
a daunting, if not impossible, task in many
developing nations.
A major challenge for the 21st century
is to develop methods of generating and us-
ing energy that meet the needs of the popu-lation while protecting the planet (Harri-
son and Pearce 2001). Yet most of the world
is still without energy policies that direct or
restrict consumption patterns.
Only through conservation and resource
recovery strategies can we hope to reach a
sustainable balance between available re-
sources and their consumption. The utiliza-
Biomass
Plant and animal material, or biomass, is a
rich source of carbon compounds. When
burned to release energy, biomass does not
add additional carbon to the natural carbon
cycle as do fossil fuels. Fast-growing plants,
such as switchgrass, willow, and poplar can
be harvested and used as “energy crops.”
Biomass wastes, including forest residues,
lumber and paper mill waste, crop wastes,
garbage, and landfill and sewage gas, can be
used for heating, as transportation fuels, and
to produce electricity, while at the same time
reducing environmental burdens. According
to the World Bank, 50 to 60 per cent of the en-
ergy used in developing countries in Asia, and
70 to 90 per cent used in developing countries
in Africa, comes from wood or other biomass;
half the world cooks with wood.
Coal
Coal is the world’s largest source of fuel for
electricity production. The byproducts of coal
combustion are also a major source of envi-
ronmental damage.
Natural Gas
Compared to coal and oil, natural gas is a
relatively clean-burning fossil fuel. It is used
primarily for heating and for powering many
industrial processes. Increasingly, natural gas
is burned to drive turbines used in the pro-
duction of electricity.
Oil
Although used primarily in the production
of transportation fuels, oil is also used for
generating electricity, for heating, and in the
production of chemical compounds and syn-
thetic materials.
Sources of Energy
Credit: Unknown/UNEP/Freefoto.com
Credit: Unknown/UNEP/Freefoto.com
Credit: Unknown/UNEP/Freefoto.com
Credit: Volker Quaschning/UNEP
Sources: www.freefoto.com, http://www.topfoto.co.uk/, Prof. Dr.-Ing. habil. Volker Quaschning http://www.volker-quaschning.de
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Wind
Wind power is an ancient energy source
that has moved into the modern era. Aero-
dynamically designed wind turbines can
produce electricity more cheaply than coal-
burning power plants.
Geothermal
Geothermal energy is energy contained in
intense heat that continually flows outward
from deep within the Earth. Geothermal
energy is typically used to heat water, which
is then used to heat buildings directly or to
drive turbines to produce electricity.
Solar
Solar energy—power from the sun—is
readily available and inexhaustible. Hu-
mans have used sunlight for heating and
drying for thousands of years. Converting
the power of sunlight into usable energy
forms, such as electricity, is not without
cost, but the sunlight itself is free. Solar
cells, or photovoltaics, are devices used to
transform sunlight into electric current.
Hydroelectric
Hydroelectric power uses the force of mov-
ing water to produce electricity. A large
part of the world’s electricity is produced in
hydroelectric plants. Many of these plants,
however, are associated with large dams that
disrupt habitats and displace people. Small-er “run of the river” hydroelectric plants
have less environmental impact.
tion of non-renewable resources is
theoretically not sustainable. But if used
wisely, some non-renewable resources can
be conserved and recycled for a very long
time. To recycle means to make new prod-
ucts from old ones. Recycling materials
such as paper, aluminum, and glass saves
energy, reduces pollution, and conserves
natural resources (EPA 2003). Every nation
must assume responsibility for recycling
its own wastes. Some industrialized West-
ern countries “dispose” of their electronic
wastes by shipping them to Asia—an in-
creasingly common practice (FOEE 2004).
To insure that renewable resources
can be replenished at a sustainable rate,
people must switch to more environmen-
tally friendly energy sources and employ
new technologies that can help make such
sustainability a reality (Ernst 2002). Indeed,
new technologies—coupled with effective
and efficient use of existing technologies—
are essential to increasing the capabilitiesof countries to achieve sustainable devel-
opment on many fronts, as well as sustain-
ing the world’s economy, protecting the
environment, and alleviating poverty and
human suffering (Hay and Noonan 2000).
Most changes in the Earth, including
changes brought about by increasing ener-
gy consumption, can be observed through
such tools as remote sensing. Remote
sensing is the collection of information
about an object without being in physical
contact with the object. Aircraft and satel-lites are the common platforms from which
remote sensing observations are made.
Satellite imagery, a crucial component of
this publication, is especially useful for
studying changes in our Earth’s environ-
ment. Most satellite imagery is collected
using multispectral scanners, which record
light intensities in different wavelengths in
the spectrum from infrared through vis-
ible light through ultraviolet light. Satel-
lite imagery is useful because of its stable
nature (same resolution, same time, same
data characteristics). Aided by the global
positioning system (GPS), these satellites
know their orbital position precisely. Thus,
satellite imagery is ideally suited for applica-
tions requiring large-area coverage, such as
agricultural monitoring, regional mapping,
environmental assessment, and infrastruc-
ture planning (Krouse et al. 2000).
Nuclear
Nuclear power harnesses the heat of ra-
dioactive materials to produce steam for
electricity generation. The use of nuclear
power is expected to decline as agingplants are taken out of operation.
Credit: Volker Quaschning/UNEP
Credit: Unknown/UNEP/Freefoto.com
Credit: Lupidi/UNEP/Topfoto
Credit: Anthony Karbowski/UNEP/Topfoto
Credit: Sanjay Singh/UNEP/Topfoto
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48
T HE BLACK T RIANGLE, EUROPE MINING
The so-called Black Triangle is an area bordered by Germany, Poland,
the Czech Republic and is the site of extensive surface coal mining op
tions. In the 1975 satellite image above, the gray areas are surface mi
located primarily in the Czech Republic. Air-borne pollutants from co
extraction activities tended to become trapped by the mountainous
rain to the northeast and were concentrated in the area around the m48
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eventually causing severe deforestation along the border between the Czech
Republic and Germany. In the 2000 image, this deforestation is very obvi-
ous, appearing as large brownish patches. Interestingly, the 2000 image also
reveals somewhat improved vegetation cover—a slight “greening” of the
landscape—as compared to conditions in 1975. Some of this improvement
may be attributable to actions taken by the three countries bordering the
Black Triangle to reduce pollutants produced by the mining operations. T
implementation of anti-pollution technologies, including circulating flui
ized-bed boilers, clean coal technology, and nitrous oxide emission burn
appears to have reversed some, albeit not all, of the environmental dama
experienced by the region as a result of the mines.
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50
COPSA MICA , R OMANIA
Copsa Mica is a large industrial city located in the very center of
Romania and is classified as an “environmental disaster area.” Th
vironmentally damaged area covers hundreds of square kilomet
land. The main industries in Copsa Mica are non-ferrous metalwo
and chemical processing plants, and their effect on the environm
has been devastating. Air pollution by heavy metals is 600 times
In one year up to 67 000 tonnes of sulfur dioxide, 500 tonnes of lead, 400
tonnes of zinc and 4 tonnes of cadmium can be released by the city’s two ac-
tive smelters. The affected area is huge: in excess of 180 000 hectares (445 000
acres) of land are affected by air pollution and 150 000 hectares (371 000 acres)
of agricultural land are untenable. 31 000 hectares (77 000 acres) of forest arealso unacceptably polluted.
50
MINING
Credit: Lorant Czaran/UNEP
¸
¸
¸
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the allowed levels. To make matters worse, a lead-smelting facility emitted
fumes containing sulfur dioxide, lead, cadmium, and zinc on the town and
surrounding area for 50 km2 (19 square miles). The entire town and much of
the surrounding area were covered with a blanket of black soot daily until the
facilities were forced to close in 1993.
In 1989 Copsa Mica was exposed as one of the most polluted places i
Europe. It has the highest infant mortality rate in Europe, 30.2 per cent o
children suffer reduced “lung function” and 10 per cent of the total popu
tion of 20 000 suffer “neurobehavioral problems.” The soil and the local f
chain probably will remain contaminated for at least another three decad
¸
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52
ESCONDIDA , CHILE
Located at an elevation of 3 050 m (10 006 ft), Chile’s Escondida
is an open-pit copper, gold, and silver mine and also the largest
per mine in the world. Isolated in the barren, arid Atacama Dese
the country’s far north, the Escondida Mine relies heavily on ext
well fields for the water used in its mining operations. Unlike sim
mining operations, however, Escondida has a redeveloped tailin52
MINING
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impoundment, which appears on the 1989 image as a white patch in the
lower left corner. Impoundments of this type help reduce water consump-
tion and enhance water conservation, two areas where mining activities
typically fall short. The Escondida Mine also minimizes the impact of its
operation on the environment by means of a 170-km-long (106 miles) un-
derground pipeline that carries copper concentrate slurry from the mine to
the port of Coloso. This underground scheme is efficient and ecologically
sound, as the copper travels downhill without disrupting the environment.
The 2003 image shows how the Escondida Mine has grown and expanded
while at the same time continues to minimize negative impacts from its
mining operations on the environment.
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54
EKATI, C ANADA
As of 2001, the Ekati Mine was North America’s only operating d
mond mine. Located in the north central Northwestern Territori
(NWT) of Canada, the mine yields raw diamonds from a sparsely
inhabited sub-arctic region. Air transport connects mine person
and supplies year-round, while a single winter ice road provides
only vehicular access just ten weeks per year.54
MINING
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Expanded mining exploration in the 1990s began a new era for this other-
wise undeveloped region. Wildlife officials have collared and tracked caribou,
in a herd ranging from 350 000 to half a million, to monitor their movement
and behavior in proximity to the mines. Historical information about the
herds comes from Dogrib and Inuit knowledge obtained from elder natives
who still inhabit the NWT, and who have depended on the caribou
for centuries.
These two images compare the same area, pre-mining and after mine
erations have commenced. The white patch in the northwest portion of
2000 image represents the mine and the associated infrastructure.
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56
OK T EDI MINE, P APUA NEW GUINEA
The controversial Ok Tedi copper mine is located at the
headwaters of the Ok Tedi River, a tributary of the Fly R iver,
in extremely rough terrain in the rainforest-covered Star
Mountains of Papua New Guinea’s western province. Prior
to the opening of the mine in 1984, this area was very
isolated, sparsely inhabited, and ecologically pristine. This56
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pair of satellite images reveals the tremendous environmental impact the
mine has had in 20 years. The uncontrolled discharge of 70 million tonnes of
waste rock and mine tailings annually has spread more than 1 000 km (621
miles) down the Ok Tedi and Fly rivers, raising river beds and causing flood-
ing, sediment deposition, forest damage, and a serious decline in the area’s
biodiversity. In the 1990 image, both the mine and the township of Tabu
bil—developed east of the river in support of the mine—are clearly visib
Lighter patches of green show disturbance of the original forest cover fro
subsistence agriculture, road clearing, and other infrastructure developm
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58
POWDER R IVER B ASIN, UNITED STATES
The Powder River basin, located in northeast Wyomin
and southeast Montana, is a core area of coal and nat
gas production in the United States. Coal mining activ
in the basin date back to 1975.
In recent years surface mining in Wyoming has mu
roomed, making it the leading coal producer in Amer58
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60
W EIPA B AUXITE MINE, A USTRALIA
Mining of bauxite (aluminum ore) began at Weipa, on the Cape
Pennisula in Queensland, Australia, in 1963. The mine produces
metric tonnes of ore annually, making it one of the world’s large
open-cut bauxite mines.
Under current mining practices, vegetation is cleared and th
topsoil is removed and either stockpiled for later use or immedi60
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replaced on previous mined areas. After topsoil removal, the bauxite is re-
moved, resulting in a lowering of the entire landscape to a depth equivalent
to the thickness of the orebody, often several meters. If the topsoil can be
returned to a mined-out area after only a short time, it still contains most of
the original soil fungi, bacteria and micro fauna. In addition, the seeds from
the original plant community are likely to be viable. On slopes, rigorous
soil conservation measures are implemented, and the area is then norma
planted with suitable native species so that it gradually reverts to bushlan
Some of the profits generated by the mining operation are being placed i
a trust for cultural protection, development and long-term investments to
compensate for the disruption of local Aboriginal inhabitants and
their environment.
The total lease covers an area of approxi-
mately 2 590 km2 (1 000 square miles) of
which 68 km2 (26 square miles) have been
mined. Approximately four km2 (1.5 square
miles) of the mined land is revegetated each
year, and over 50 km2 (19 square miles) of
land has been revegetated to date.
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62
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Daylight Map of the World
Credit: UNEP/NASA
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66Credit: Hu Zong Huu/UNEP/Topfoto
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3Human Impacts on the PlanetVisualising Change over Time
Human interactions with the environment
leave many traces. For much of human
history, human impact on the Earth’s
surface has been relatively minor. In the
last several hundred years, however, that
impact has grown tremendously. Change
brought about by human activities can now
be objectively measured; it can even be
seen from space. A study by the National
Aeronautics and Space Administration
(NASA 2003a) known as The Human Foot-
print (Figure 3.1) is a quantitative analysis
of human influence across the globe that
illustrates the impact of people and theiractivities on the Earth.
Evidence of change is not always vis-
ible on the landscape. Change also occurs
in the atmosphere, in the soil, and in the
oceans and other water bodies. In these
environments, evidence of change can
still be “seen,” however, by detecting and
measuring things such as rising average
global temperatures, the concentrations of
certain gases in the atmosphere, and vari-
ous chemical contaminants in water.
Change alone is not the only problem.It is the degree to which human activities
are changing the Earth that is also cause
for growing concern. For instance, the
results of a recent ten-year study concern-
ing the ecological effects of industrialized
fishing in the world’s oceans reveals that
large predatory fish species including
tuna, marlin, sharks, cod, and halibut have
declined by an estimated 90 per cent from
pre-industrial levels (Myers and Warm
2003). Furthermore, the average size of
surviving individuals among these species
is only one-fifth to one-half what it was
previously.
The composition of the Earth’s atmo-
sphere is also undergoing rapid change.
Since life began on Earth, changes in
climate have ordered the distribution of
Map of the Human Footprint
Figure 3.1: The Human Footprint is a quantitative analysis of human influence on the Earth’s surface. In this
map, human impact is rated on a scale from 0 (minimum) to 100 (maximum) for each terrestrial biome. Thecolor green indicates areas of minimal impact while purple indicates areas of major impact.Credit: Scott, Michon 2003. The Human Footprint. NASA: Socioeconomic Data and Applications Center. Source: http://earthobservatory.nasa.gov/Newsroom/ NewImages/Images/human_footprint.gif
Credit: Apollo Mbabaz/UNEP/Topfoto
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8
organisms and their behavior. Today,
increases in atmospheric concentrations
of greenhouse gases are expected to cause
more rapid changes in the Earth’s climate
than have been experienced for millennia
(Figure 3.2). At least some of the increase
globally is due to human activity, and
certainly, local impacts such as urban heat
islands have profound effects on regional
climatic conditions. As shown in Figure 3.2,
waste generation and disposal is one of the
ways in which humans contribute green-
house gases to the atmosphere.
An emerging global impact issue is that
of electronic or E-waste—a collective term
for discarded electronic devices. Over the
past decade, E-waste has become one of
the world’s fastest growing waste streams
and—due to the presence of lead, mer-
cury, brominated flame retardants, and
other hazardous substances—one of the
most toxic. The disposal of computer waste
in particular is becoming a difficult issue as
millions of computers and other electronic
devices are rapidly becoming obsolete as
each year the industry produces ever-great-
er quantities of less-expensive equipment.
There are an estimated 300 million obso-
lete computers in the United States, with
fewer that ten per cent destined for recy-
cling each year. Even when a computer is
sold to a secondhand parts dealer, however,
there is a good chance it will end up
in a dump in the developing world
(Figure 3.3).
The Earth’s forests are also under
pressure. Tropical forests are now being
subjected to the same heavy exploitation
as were temperate forests a few genera-
tions ago. Pressures from logging, mining,
hydropower, and a hunger for land are
Figure 3.2: The disposal and treatment of waste can
produce emissions of several greenhouse gases that contribute to global climate change. Even the recy-
cling of waste produces some emissions, althoughthese are offset by the reduction in fossil fuels that
would be required to obtain new raw materials. Both waste prevention and recycling help address global
climate change by decreasing greenhouse gas emis-sions and saving energy (Environmental Protection
Agency). Source: http://www.grid.unep.ch/waste/html_file/42- 43_climate_change.html
Credit: Paiboon Pattanasitubol /UNEP/Topfoto
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leading to large areas of forest being con-
verted to serve other purposes. The integ-
rity of forest ecosystems is being affected
as the timber and paper industries remove
vast areas of mature tropical and temperate
forests. As a consequence, forest ecosys-
tems lose their ability to support complex
biodiversity and thousands of plant and
animal species disappear forever.
Several globally significant environ-
mental trends that have occurred between
1980 and 2000 may also be contributing to
loss of forest ecosystems, including global
warming (the two warmest decades on
record are the 1980s and 1990s), three in-
tense El Niño events, changes in cloudiness
and monsoon dynamics, and a 9.3
per cent increase in atmospheric CO2. Al-
though these factors, along with others, are
thought to exert their influence globally,
their relative roles are still unclear.
An observed decline in tropical cloud
cover is probably one of the more impor-
tant recent climatic changes, although
none of the existing climate models can
accurately simulate this effect. It is known
that continued reductions in tropical cloud
cover, if accompanied by reduced rainfall,
will have profound implications for tropical
ecosystems in terms of water stress, produc-
tivity, ecological community composition,
and disturbance patterns.
Images of Change
Various types of ground-based instruments,together with in situ surveys and analyses,
can measure many of the changes being
brought about on the Earth as a result of
human activities. But such changes can
also be observed—in more detail and with
a “big picture” perspective—from space by
Earth-orbiting satellites that gather images
of the Earth’s surface at regular intervals.
The Landsat series of Earth-observing
satellites has compiled a data record of the
planet’s land surfaces that spans the past
thirty years and continues today.
By comparing two images of the same
area taken ten, twenty, or even thirty years
apart, it is often easy to see human-induced
changes in a particular landscape. Few
places remain on our planet that do
not show at least some impact from
human activities.
The focus of this chapter is a set of
specific case studies in which satellite im-
ages, taken at different times, are paired
so as to reveal changes and human impacts
on the atmosphere, oceans and coastal
zones, freshwater ecosystems and wetlands,
forests, croplands, grasslands, urban areas,
and the tundra regions.
The changes that we see in pairs of
satellite images should make us cautious.
Some are positive changes. But many more
are negative. These images could be seen
as warning signs. At the least they should
provide us with food for thought and
prompt us to ask pointed questions: How
can we be more protective of our environ-
ment? How can we use the environment in
ways that will not reduce the ability of the
Earth to support us in perpetuity?
Figure 3.3: The high tech boom has been accompanied by E-waste, which rep-
resents the largest and fastest-growing type of manufacturing waste product.Recycling E-waste involves major producers and users, and the shipping of
obsolete equipment and other products to Asia, Eastern Europe, and Africa whererecyclers, such as the people in this photo, are exposed to toxic substances.Source:
http://www.grid.unep.ch/waste/html_file/36-37_ewaste.html
Credit: Unknown/UNEP/Basel Action Network
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0
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Credit: Unknown/UNEP/Morgue File
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2
The Earth’s atmosphere is a collec-
tion of gases, vapor, and particu-
lates that together form a blanket
of “air” that surrounds the planet. The
atmosphere extends over 560 km (348
miles) from the surface of the Earth out
toward space, and can be roughly dividedinto five major layers or sections (Figure
3.4). The primary components of the at-
mosphere are three gases: nitrogen (N2, 78
per cent), oxygen (O2, 21 per cent), and
argon (Ar, 1 per cent). Other components,
present in smaller amounts, include water
vapor (H2O, 0-7 per cent), ozone (O3, 0-
0.01 per cent), and carbon dioxide (CO2,
0.01-0.1 per cent) (Phillips 1995).
The Earth’s atmosphere plays many
vital roles essential to sustaining life on
the planet. The air we breathe circulatesthrough its lowest level. The chemical ele-
ments carbon, nitrogen, oxygen, and hy-
drogen, which are constituents of all living
things, are cycled and recycled in the atmo-
sphere. Organisms convert these elements
into carbohydrates, proteins, and other
chemical compounds. The atmosphere
also shields life on the planet’s surface
from harmful solar radiation, and—for the
most part—from the threat of meteorites,
which typically burn up as they go through
the atmosphere (UNEP 1999a).
Human activities impact the Earth’s
atmosphere in many ways. Some activities
produce a quite direct effect, such as gen-
erating and releasing pollutants that foulthe air, and adding carbon dioxide and
other greenhouse gases to the atmosphere
that induce global warming and climate
change. Other human impacts, such as
water pollution, land degradation, and
human-induced loss of biodiversity, can
indirectly affect the atmosphere, as well as
the water and land.
In this section, four major issues that in-
volve human impacts on the atmosphere—
ozone depletion, global warming, climate
change, and air pollution—are addressed.
Ozone Depletion
Ozone is a relatively unstable molecule,
made up of three oxygen atoms (O3). Inthe atmosphere, ozone is formed naturally
in the stratosphere. It is concentrated
there as an “ozone layer” that acts as a
protective shield against harmful ultravio-
let (UV) radiation coming from the Sun.
The loss of stratospheric ozone allows
more UV radiation to reach the Earth’s
surface, where it can cause skin cancer and
cataracts in people and negatively affect
other living things as well.
Ozone is also found in the troposphere,
the layer of the Earth’s atmosphere that is
closest to the planet’s surface. Ozone can
3.1 Atmosphere
Figure 3.4: The Earth’s atmosphere Credit: Used with permission from Centre for Atmospheric Science, University of Cam- bridge, UK. Source: http://www.atm.ch.cam.ac.uk/tour/atmosphere.html
Exosphere
Thermosphere
Mesosphere
StratosphereTroposphere
300 km
400 km altitude
50 km
40 km
10 km
Credit: Image Analysis Laboratory/UNEP/NASA Johnson Space Center
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be formed naturally in the troposphere—
for example, by lightning. However,tropospheric ozone is also a byproduct of
certain human activities. Vehicle exhaust
contributes large quantities of ozone to the
troposphere each year.
Depending on where ozone resides,
it can protect or harm life on the Earth
(Figure 3.5). In the stratosphere, ozone
is “good” as it shields life on the surface
from harmful solar radiation. In the tropo-
sphere, ozone can be “bad” as it becomes
a type of air pollution. Changes in the
amount of ozone in either the stratosphere
or the troposphere can have serious
consequences for life on the Earth. For
several decades, “bad” tropospheric ozone
has been increasing in the air we breathe,
while “good” stratospheric ozone has been
decreasing, gradually eroding the Earth’s
protective ozone shield (Thompson 1996).
Since the late 1970s, scientists have
detected a slow but steady decline in the
amount of ozone in the stratospheric
ozone layer. This ozone destruction re-sults from the presence of certain types
of chemicals in the atmosphere, espe-
cially chlorofluorocarbons (CFCs) and
other chlorine- and bromine-containing
compounds, coupled with fluctuations in
stratospheric temperature.In polar regions, particularly the area
of the atmosphere that overlies Antarctica,
ozone depletion is so great that an “ozone
hole” forms in the stratosphere there every
Ozone in the Earth’s Atmosphere
Stratosphere:
Troposphere: Earth
Mesosphere
In this region, ozone is
“bad.” It can damage
lung tissure and plants.
In this region, ozone
is “good.” It protects
us from the sun’s
harmful ultraviolet
radiation.
Figure 3.5: Ozone in the stratosphere forms the protective ozone layer that shields the Earth’s sur-face from harmful solar radiation. Ozone in the troposphere, the lowest part of the atmosphere,can be a form of air pollution. Source: http://www.atmos.umd.edu/~owen/CHPI/IMAGES/ozonefig1.html
Credit: Image Analysis Laboratory/UNEP/NASA Johnson Space Center
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4
austral spring (late August through early
October). In the past few years, the Ant-arctic ozone hole has been about the size
of North America. In 2000, the Antarctic
ozone hole was the largest on record,
covering 29.6 million km2 (11.4 million
square miles). In the austral spring of
2003, it was almost as large, covering 28.9
million km2 (11.1 million square miles)
(Figure 3.6).
Seasonal ozone depletion is also
noticeable around the North Pole. More
than 60 per cent of stratospheric ozone
north of the Arctic
Circle was
lost during the winter and early spring of
1999-2000 (Shah 2002).Some ozone-depleting chemicals, such
as CFCs, also contribute to global warm-
ing. Like carbon dioxide and methane,
CFCs are powerful greenhouse gases
that trap heat radiating from the Earth’s
surface and prevent it from immediately
escaping into space. This causes the part
of the atmosphere nearest the Earth’s sur-
face to warm, resulting in global warming.
This warming in the troposphere, how-
ever, leads to colder-than-normal tempera-
tures in the stratosphere. This, in turn,
enhances the formation of certain types of
stratospheric clouds that foster ozone-de-
stroying chemical reactions in the strato-
sphere (Shanklin n.d.).
Fortunately, bans against the produc-
tion and use of CFCs and other strato-spheric ozone-destroying chemicals ap-
pear to be working to reverse the damage
that has been done to the ozone layer. In
the past few years, the Antarctic ozone
hole has not increased significantly in size
Figure 3.7: Growth of the Antarctic ozonehole over 20 years, as observed by the satel-lite-borne Total Ozone Mapping Spectrometer(TOMS). Darkest blue areas represent regionsof maximum ozone depletion. Atmosphericozone concentration is measured in DobsonUnits. A “normal” stratospheric ozone mea-surement is approximately 300 Dobson Units.
Measurements of 220 Dobson Units and below represent significant ozone depletion. Source: http://www.gsfc.nasa.gov/topstory/2004/0517aura.html
1979
1982
1984
1986
1988
24 Sep 200306 Sep 2000
Ozone • Total Ozone Mapping Spectrometer (TOMS)
Figure 3.6: Every austral spring, an area of severe stratospheric ozone depletion— an “ozonehole”—forms in the atmosphere over Antarctica. The ozone holes that formed in 2000 and 2003
were the largest and second largest on record, respectively. Source: http://www.gsfc.nasa.gov/gsfc/earth/ pictures/2003/0925ozonehole/still_hires_24Sept2003.tif and http://www.gsfc.nasa.gov/ftp/pub/ozone/ozone_still_2000_09_06.tif (NASA 2004a)
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1990
1992
1994
1997
1999
or intensity. Some researchers predict that
if atmospheric concentrations of ozone-de-
stroying chemicals drop to pre-ozone-hole
levels, the Antarctic ozone hole should dis-
appear in approximately 50 years (Figure
3.7) (WMO-UNEP 2002).
Global Warming
Atmospheric temperature and chemistry
are strongly influenced by the amount
and types of trace gases present in the
atmosphere. Examples of human-made
trace gases are chlorofluorocarbons, such
as CFC-11, CFC-12, and halons. Carbon
dioxide, nitrous oxide, and methane (CH4)
are naturally formed trace gases produced
by the burning of fossil fuels,
released by living and
dead biomass,
and resulting from various metabolic
processes of microorganisms in the soil,
wetlands, and oceans. There is increasing
evidence that the percentages of environ-
mentally significant trace gases (green-
house gases) are changing due to both
natural and human factors, and contribut-
ing to global warming.
Global warming is recognized as one of
the greatest environmental threats facing
the world today. Global warming is the
gradual rise of the Earth’s average surface
temperature caused by an enhancing of the
planet’s natural greenhouse effect. Radi-
ant energy leaving the planet is naturally
retained in the atmosphere thanks to the
presence of certain gases such as water
vapor and carbon dioxide. This heat-trap-ping effect is, in fact, what makes life on the
Earth possible.
Global warming, by contrast, is an
intensification of the Earth’s greenhouse
effect. The Earth’s average surface tem-
perature, which has been relatively stable
for more than 1 000 years, has risen by
about 0.5 degrees Celsius in the past 100
years (Figure 3.8). The nine warmest
years in the 20th century have all occurred
since 1980; the 1990s were probably the
warmest decade of the second millennium
(IPCC 2001).
Global warming has occurred in the dis-
tant past as the result of natural influences.
However, since the industrial era, the term
is most often used to refer to the current
warming predicted as a result of increases
in the atmospheric concentrations of cer-
tain heat-trapping greenhouse gases gener-
ated by human activities (Figure 3.9).
Most scientists
Credit: John Bortniak/UNEP/NOAA
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believe that much of this global tempera-
ture increase is due to increased use of
fossil fuels, which when burned, release
carbon dioxide into the atmosphere where
it absorbs infrared radiation that normally
would pass through the atmosphere and
travel out into space (Brehm 2003).
The planet is not as warm as it was ap-
proximately 1 000 years ago (Figure 3.10).
Nevertheless, CO2 currently accounts for
the greatest proportion of greenhouse gas
emissions. Much of the CO2 added to the
atmosphere comes from the burning of
fossil fuels in vehicles, for heating,
and for the production of electricity
(Figure 3.11).
In addition to carbon dioxide, ris-
ing levels of methane in the atmosphere
are also of concern. The relative rate of
increase of methane has greatly exceeded
that of carbon dioxide in the last several
decades. Methane is released into the
atmosphere in many ways: as a result of ag-
riculture and ranching activities; through
the decay of organic matter, including
waste dumps; through deforestation; and
as a by-product of the hydrocarbon econo-
my. None of these sources are anticipated
to decrease in the future. On the contrary,
methane emissions are expected to in-
crease, as each year an additional 100 mil-
lion people require food and fuel as world
population expands (Figure 3.12).
Most scientists believe that recent
global warming is mainly due to humanactivities and related increases in concen-
trations of greenhouse gases (Figure 3.13),
primarily CO2, CH4, nitrous oxide (N2O),
hydrofluorocarbons (HFCs), perfluoro-
carbons (PFCs), and sulfur hexafluoride
(SF6). These changes are driven by world-
wide population and economic growth,
and the underlying production and
consumption of fossil fuels, as well as by
the intensification of agricultural activity
and changes in land use and land cover.
Energy production and use, the largest sole source of CO2 emissions and a large
contributor of CH4 and N2O emissions, ac-
counted for 81.7 per cent of emissions in
industrialised countries in 1998
(UNFCCC 2000).
From far out in space, instruments
carried aboard satellites, such as NASA’s
Figure 3.9: Human activities directly influence the abundance of greenhouse gases and aerosols inthe atmosphere. Carbon dioxide, nitrous oxide, methane, and sulfur aerosols have all increasedsignificantly in the past 50 years. Source: Intergovernmental Panel on Climate Change, IPCC (2001)
Figure 3.10: Variations in the Earth’s temperature for the past 140 years (global) and for the past 1 000 years (Northern Hemisphere). Source: IPCC (2001)
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Moderate Resolution Imaging Spectrora-
diometre (MODIS) sensor, are taking the
temperature of the Earth’s surface. Satel-
lite data confirm that the Earth’s average
surface temperature has been slowly rising
for the past few decades (Figure 3.14).
Satellite records are more detailed and
comprehensive than previously available
ground measurements, and are essential
for improving climate analyses and com-
puter modeling.
One of the more predictable effects of
global warming will be a rise in sea levels
(Figure 3.15). It is already under way at
a pace of about a millimetre a year—a
consequence of both melting land ice and
the thermal expansion of the oceans (Har-
rison and Pearce 2001). Predictions as to
how much global sea levels may rise over
the next century range from half a metre
(1.5 feet) (Houghton et al. 2001) to be-
tween 1 and 2 m (3 to 6 feet) (Nicholls et
al. 1999). Such an increase would drownmany coastal areas and atoll islands. Un-
less countries take action to address rising
sea levels, the resulting flooding is ex-
pected to impact some 200 million people
worldwide by the 2080s. In addition,
around 25 per cent of the world’s coastal
wetlands could be lost by this time due to
sea-level rise (DETR 1997).
Global warming may have some posi-
tive impacts. It could, for example, open
Figure 3.13: The role of different gases and aerosols in global warming. Source: IPCC (2001)
Figure 3.14: Global warming is an increase inthe Earth’s average surface temperature. Thesegraphs illustrate how a shift in the mean temper-ature and its variance can affect weather. Source: IPCC (2001)
Figure 3.12: Methane is the second largest contributor to global warming and its atmosphericconcentration has increased significantly over the last two decades. Methane emissions fromhuman-related activities now represent about 70 per cent of total emissions, as opposed to lessthan 10 per cent 200 years ago. Source: IPCC (2001)
Figure 3.11: Between 1971 and 1998, energy use and carbon dioxide emissions both increasedsignificantly, contributing to the likelihood of global warming. Source: IPCC (2001)
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new lands for agriculture and forestry in
the far north. During the past 30 years in
Iceland, old farmlands have been exposed,
and are being used, as the Breidamerkur-
jökull Glacier has receded. All told,
however, the negative impacts of un-
checked global warming outweigh any
positive benefits.
Climate Change
Climate is the statistical description in
terms of the mean and variability of rel-
evant measures of the atmosphere-ocean
system over periods of time ranging from
weeks to thousands or millions of years.
Climate change is defined as a statistically
significant variation in either the mean
state of the climate or in its variability,
persisting for an extended period (typically
decades or longer). Climate change may be
due to natural internal processes or to ex-
ternal forcing (Figure 3.16). Volcanic gases
and dust, changes in ocean circulation,
fluctuations in solar output, and increased
concentrations of greenhouse gases in the
Figure 3.15: Reasons for sea level change Source: IPCC (2001)
European Heat Wave, July 2003 Credit: NASA— Satellite Thermometers Show Earth Has a Fever (2004)
Case Study: European Heat Wave
July 2003
This image shows the differences
in daytime land surface temperatures
(temperature anomalies) collected over
Europe between July 2001 and July 2003
by the Moderate Resolution Imaging
Spectroradiometer (MODIS) on NASA’s
Terra satellite. A blanket of deep red across
southern and eastern France (left of im-
age center) reveals that temperatures in
this region were 10ºC (18ºF) hotter dur-ing 2003 than in 2001. Temperatures were
similar in white areas and cooler in blue
areas. Although models predict an overall
increase in global average temperatures,
regional differences may be pronounced,
and some areas, such as mid-continental
zones in North America and Asia, may
actualy experience some degree of cooling
(NASA 2003c).
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atmosphere can all cause climate changes
(USCCSP 2003).
Global warming, whatever its underly-
ing causes, is expected to have adverse,
possibly irreversible effects on the Earth’s
climate, including changes in regional tem-
perature and rainfall patterns and more
frequent extreme weather events. Climate
change will affect the ecology of the planet
by impacting biodiversity, causing species
extinctions, altering migratory patterns,
and disturbing ecosystems in countless
ways. Climate change will impact human
societies by affecting agriculture, water
supplies, water quality, settlement patterns,
and health.
Overall, climate change is likely to in-
tensify the already increasing pressures on
various sectors. Although the impact of cli-
mate change may, in some cases, be smaller
than other stresses on the environment,
even relatively small changes can have seri-
ous adverse effects, especially where there
may be critical thresholds, where
development is already marginal, or where
a region is less able to implement adapta-
tion measures (DETR 1997).
For example, climate change is likely
to exacerbate already increasing pressure
being put on water resources by a growing
global population, particularly in Africa,
Central America, the Indian subcontinent,
and southern Europe. By the 2050s, mod-
els indicate that there may be an additional
100 million people living in countries with
extreme water stress due to climate change
alone (DETR 1997).
Figure 3.16: Climate change is the result of complex interactions among many factors. Source: IPCC (2001)
Credit: Unknown/UNEP/Topfoto
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heavily industrialized areas of both Europe
and North America into prime agricultural
areas that lay downwind. Mountain regions
suffered the most because their higher
rainfall increased the volume of acid depo-
sition and their often thin soils could not
neutralize the acid. Lakes and streams in
pristine parts of Scandinavia and Scotlandbecame acidified, and fish populations
were decimated in some areas. The most
intense acid rain fallout occurred in the
so-called Black Triangle region bordered
by Germany, Czech Republic, and Poland
(Harrison and Pearce 2001) (Figure 3.19).
Acid precipitation decreased through-
out the 1980s and 1990s across large por-
tions of North America and Europe. Many
recent studies have attributed observed
reversals in surface-water acidification at
national and regional scales to this de-
cline (Stoddard et al. 1999; Larssen 2004).
Decreases in acid precipitation have been
achieved largely through improved flue gas
treatments, fuel switching, use of low-sulfur
fuels in power stations, and use of catalytic
converters in automobiles. Since 1985,
international treaties and heavy investment
in desulphurization equipment by power
station operators have cut sulfur pollutionin Europe and North America by as much
as 80 per cent (Harrison and Pearce 2001).
Although significant progress has been
made in controlling acid-forming emissions
in some countries, the global threat from
acid precipitation still remains. In fact, the
problem is growing rapidly in Asia, where
1990s-level SO2 emissions could triple by
2010 if current trends continue. Curtailing
the already substantial acid precipitation
damage in Asia, and avoiding much more
severe damage in the future, will require
investments in pollution control similiar to
those made in Europe and North America
over the past 20 years (Downing 1997;
WRI 1998).
Nitrogen dioxide is the orange gas that
is the most visible component of most air
pollution. In many cities, NO2 and other
pollutants are suspended in the air to form
a brownish haze commonly called smog.Nitrogen dioxide is formed when oxygen
in the air combines with nitric oxide.
Nitric oxide comes from automobiles,
aerosols, and industrial emissions, and
contributes to the formation of acid rain.
In addition, this pollutant can cause a wide
range of environmental damage, including
eutrophication of water bodies—explosive
algae growth that can deplete oxygen and
kill aquatic organisms.
Fig.3.19: Aerosols affect climate both directly by reflecting and absorbing sunlight and indirectly by modifying clouds. The Total Ozone Mapping Spectrometer(TOMS) aerosol index is an indicator of smoke and dust absorption. This figure shows aerosols—the hazy green, yellow, and red patches—crossing the Atlantic andPacific Oceans. Dust from the Sahara Desert is carried westward toward the Americas and provides nutrients for Amazon forests. Asian dust and pollution travel to
the Pacific Northwest. Source: NASA (http://www.gsfc.nasa.gov/topstory/2004/0517aura.html) (NASA 2004a)
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Case Study: Emissions in Paris
1999-2003
Paris, France, lies on a relatively flat plain.
Most of the time, Paris benefits from a wet
and windswept oceanic climate that en-
courages the dispersal of air pollution and
thus cleans the air. However, under certain
meteorological conditions (anticyclones
and a lack of wind), pollutants can remain
trapped in the atmosphere above the city,
where they become concentrated, resulting
in significantly higher levels of pollution.
Thus, for equivalent pollutant emissions in
terms of location and intensity, the levels of
pollutants recorded in the atmosphere can
vary by a factor of 20 according to meteoro-
logical conditions.
This explains why peaks in secondary
pollutants often affect wider areas than
peaks in primary pollutants. For example,
when the wind blows from the city in a
certain direction, the rural area surround-
ing the Paris region is also subject to ozone
pollution. Indeed, ozone levels registered
in these areas are often much higher than
those in the centre of Paris itself.
In 1994, according to the Centre
Interprofessionnel Technique d’Etude
de la Pollution Atmosphérique (CITEPA,
Inter-professional Technical Centre for
Research into Air Pollution) SO2 emissions
in the Paris region corresponded to eight
per cent of national emissions (mainland
France and overseas territories), oxides
of nitrogen (NOx) emissions to 10per cent, Volatile Organic Compound
(non-methane) (VOCNM) emissions to 12
per cent, carbon monoxide (CO) emis-
sions to 15 per cent, and CO2 emissions to
14 per cent. Given that 19 per cent of the
population lives in the Paris region, emis-
sions per inhabitant in this area are less
than the national average for all substances
(CITEPA 1994).
Existing air-quality-monitoring tools
in the greater region of Paris provide a
constant indication of air pollution levelsat specific background and roadside loca-
tions. In addition to standard monitoring,
specific modeling applications give ex-
tensive descriptions of air-quality patterns
for several significant pollutants. Despite
the involvement of the transport sector in
monitoring local atmospheric emissions,
there is no direct and constant trafficdata feed. Recently, a project known as
HEAVEN (Healthier Environment through
the Abatement of Vehicle Emissions and
Noise) was implemented in Paris. Its main
objective was to integrate real-time traffic
information with the air quality monitoring
tools. HEAVEN helped develop and dem-
onstrate new concepts and tools to allowcities to estimate emissions from traffic in
near-real time. This enhanced the identifi-
cation and evaluation of the best strategies
for transport demand management.
Souce: http://heaven.rec.org
Concentrations of SO2, NOx, CO, and VOC over Paris. Source: http://www.airparif.asso.fr/english/polluants/default.htm
Annual SO2 emmissions in the Paris region Annual NOx emmissions in the Paris region
Annual CO emmissions in the Paris region Annual VOC emmissions in the Paris region
Air quality dynamics over the region of Paris, France, from 1999 to 2003. Source: http://www.airparif.asso.fr/eng- lish/polluants/default.htm
Annual averages of SO2 in Ile-de-France from1999 to 2003
Regional cartography of the annual level of benzene evaluated within the framework of theEuropean project LIFE “RESOLUTION”
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Northern Hemisphere seasonal variation in atmospheric carbon monoxide and its global distribution. Source: http://svs.gsfc.nasa.gov/vis/a000000/a002100/ a002150/ (NASA 2004d)
Case Study: Pollution from Wild Fires
2003–2004
Whether started by people or natural
events, fires add large quantities of pollut-
ants to the atmosphere every year, primar-
ily in the form of CO and aerosols. Satellite
sensors can help researchers distinguish
between wildfires and urban or industrial
fires. Some can also distinguish different
types of fire-generated pollutants. Forinstance, two sensors aboard NASA’s Terra
satellite—the Measurements of Pollution
in the Troposphere (MOPITT) instru-
ment and the Moderate Resolution Imag-
ing Spectroradiometer (MODIS) instru-
ment—gather data on CO and aerosols,
respectively.
Carbon monoxide is one of the more
easily mapped air pollutants. In the
MOPITT-generated series of maps shown
below, global seasonal variations in CO
concentration are clearly visible (high-
est concentrations of CO appear as red).
Major concentrations of CO during dif-
ferent seasons can be easily identified and
tracked over time on such images, leading
to better understanding of sources of CO
pollution and its transcontinental trans-
port (NASA 2004d). For example, in the
summer image of this series, a very high
concentration of CO appears over west
central Africa, largely due to forest fires.
Wildfires in southern Africa are a ma-
jor source of carbon monoxide pollution.Every August in southern Africa, thou-
sands of people equipped with lighters or
torches travel out onto the savanna and
intentionally set the dry grasslands ablaze.
Burned grasses send up tender new growth
that is ideal for cattle consumption. The
fires typically scorch an area the size of
Montana, Wyoming, Idaho, and the Dako-
tas combined. Long plumes of smoke rise
like hundreds of billowing smokestacks,
and herds of animals are sent scurrying
across open grassland.
During this fire season, a thick pall of
smoke clouds the sky for many weeks. The
smoke is laced with a number of pollut-
ants, including nitrogen oxides, carbon
monoxide, and hydrocarbons. Some of
these substances react with the intense
heat and sunlight to form ozone. Ground-
level ozone contributes to respiratory
diseases and can seriously damage crops.
At higher levels in the troposphere, ozone
molecules trap thermal radiation emanat-
ing from the Earth’s surface in the same
way as carbon dioxide and other green-
house gases do. In fact, up to 20 per cent
of the global warming experienced by the
Earth over the past 150 years is thought to
be from ozone.
In the spring of 2003, the MODIS and
MOPITT instruments were used to moni-
tor fires and fire-produced air pollutants
in Siberia, especially in the Baikal region.
These fires produced large amounts of fine
carbon aerosols that spread out over the
Pacific Ocean and remained suspended
in the atmosphere for a few days. Carbon
monoxide was also produced by the fires,
4
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but unlike the aerosols, remained airborne
for a much longer period of time, allowing
it to cross the Pacific Ocean and reduce air
quality over North America before continu-
ing on around the globe.
Gas and particle emissions produced
as a result of fires in forests and other
vegetation impact the composition of the
atmosphere (WHO 2000). These gases and
particles interact with those generated by
fossil-fuel combustion or other technologi-
cal processes, and are major causes of ur-
ban air pollution. They also create ambient
pollution in rural areas. When biomass fuel
is burned, the process of combustion is not
complete and pollutants released include
particulate matter, carbon monoxide, ox-
ides of nitrogen, sulfur dioxide and organic
compounds. Once emitted, the pollut-
ants may undergo physical and chemical
changes. Thus, vegetation fires are major
contributors of toxic gaseous and particle
air pollutants into the atmosphere. Thesefires are also sources of “greenhouse” and
reactive gases. Particulate pollution affects
more people globally on a continuing
basis than any other type of air pollu-
tion. In 1997/98, forest fires in Southeast
Asia affected at least 70 million people in
Brunei Darussalam, Indonesia, Malaysia,
the Philippines, Singapore, and Thailand.
Thousands of people fled the fires and
smoke and the increase in the number of
emergency visits to hospitals demonstrated
the severity of the fires and pollution they caused (WHO 2000).
Case Study: African Fires
2002
Wildfires—from forest fires and brush fires
to grass fires and slash-and-burn agricul-
ture—can be sweeping and destructive
conflagrations, especially in wilderness or
rural areas. As biomass burns, particulates,
black carbon, and gases including CO2,
CO, NOx, CH4, and CH3Cl are produced
in great quantities. All of these pollutants
can be lofted relatively high in the atmo-
sphere due to the convective heating of a
raging fire (Graedel and Crutzen 1993).
The image at right shows fire activity in
Africa from 1 January 2002 to 31 Decem-
ber 2002. The fires are shown as tiny dots
with each dot depicting the geographic re-
gion in which fire was detected. The color
of a dot represents the number of days
since a sizable amount of fire was detected
in that region, with red-orange represent-
ing less than 20 days, orange representing
20 to 40 days, yellow representing 40 to 60
days, and gray to black representing more
than 60 days. These data were gathered
by the MODIS instrument on the Terra
satellite. MODIS detects fires by measuring
the brightness temperature of a region in
several frequency bands and looking for
hot spots where this temperature is greater
than the surrounding region.
Global statistics on the amount of land
burned worldwide every year vary consid-
erably. It has been estimated that from
7.5 million to 8.2 million km2 (4.6 million
to 5.1 million square miles) are burned
and between 1 800 million and 10 000
million metric tonnes of dry biomass are
consumed in fires annually. Global change
scenarios predict an increase in total area
burned, with an increase in very large and
intense fires.
Pollution outflow from spring 2003 fires in Siberia can be seen in the top and middle image.These fires produced large amounts of fine carbon aerosol detected by MODIS instrument (bright colours) on the Terra satellite, which spread over the Pacific Ocean but lasted only a few days. They also produced carbon monoxide, which was detected by the MOPITT instrument onthe Terra satellite (bottom image). This gas can last over a month, which allowed it to cross thePacific Ocean and reduce air quality over North America before continuing on around the globe.
Credit: David Edwards, The National Center for Atmospheric Research (NCAR) (NASA 2004e)
African Fires during 2002 Credit: http://svs.gsfc.nasa.gov/vis/a000000/a002800/a002890/index.html (NASA 2004f)
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Credit: Chia/UNEP/Morgue File
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Credit: Darren H.Holto/UNEP/Topfoto
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Oceans cover roughly 70 per cent of the Earth’s surface andmake up some 90 per cent of space habitable by livingthings. They contain a vast, and largely unexplored, di-
versity of life, from the smallest of microorganisms to blue whales,the largest mammals on the Earth. Oceans are essential for theecological functions and resources they provide, including food,medicines, and energy for millions of people worldwide (UNEP-
WCMC 2003).
The world’s oceans have a great effect on global climate. Water has a high capacity for retaining heat. Because so much of the Earth’s surface is covered by oceans, the temperature of theatmosphere is kept fairly constant and within the range neces-sary to support life. Currently, the oceans also moderate climatechange by absorbing a third of the carbon dioxide (CO2) emittedinto the air by human activity (Harrison and Pearce 2001). Howev-er, global warming may reduce the ocean’s capacity to act as a CO2 sink by 10 to 20 per cent over the next century (Houghton et al. 2001).
Different parts of the globalocean affect climate indifferent ways. TheIndian Ocean/West Pacific Warm Pool,
for example, is anenormous ex-panse of warmsurface water.It extendsalmost half
way aroundthe Earth,stretch-ing alongthe equa-tor southof India,through the
waters off
Sumatra, Java,Borneo, andNew Guinea,and into the cen-tral Pacific Ocean.The waters of the
Warm Pool are warmerthan any other area of openocean on the Earth. Becausethese waters are warm to enough to drive mois-ture high into the atmosphere, the Warm Pool has a large effect onthe climate of the lands that surround it. The slow fluctuations insize and intensity of the Warm Pool may be linked with the inten-sity of the El Niño phenomenon.
In addition to the ocean’s climate-buffering capacity, its salty waters contain billions of tiny algae and other planktonic organ-isms. These life forms carry out a large part of the oxygen-gener-ating photosynthetic processes that occur on the planet (BiomesGroup 1996). For people, oceans represent one of the greatest sources of food on the Earth as well. Global fish productionexceeds that of cattle, sheep, poultry, or eggs. It represents thelargest source of wild or domestic protein in the world (UNEP-
WCMC 2003). Marine fish catch rose from 51 million metrictonnes in 1975 to nearly 70 million metric tonnes in 1999(UNEP 2002).
3.2 Coastal Areas
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Coastal zones, which include bays, tidal lands, estuaries, marine wet-lands, mangroves, and coral reefs, form an interface between the land and
the ocean. The total length of all the world’s coastlines is estimated to beroughly 1.6 million km (1 million miles) (Burke et al. 2000).
Many coastal marine ecosystems are among the most productivein the world, rich in living and nonliving resources. Mangroves, for
example, extend over 18 million hectares (44 million acres) world- wide, covering a quarter of the world’s tropical coastlines (Choud-
hury 1997). Mangroves protect coastlines by absorbing the forceof storms. They provide large quantities of food and fuel, build-ing materials, and even medicines. Mangroves are also charac-terized by nutrient-rich waters that support large numbers of
marine organisms and, in many cases, form nursery groundsfor fish and other marine species. Because of their tremendousproductivity, mangroves and other coastal ecosystems providefood and livelihood for millions of people.
In many warm-ocean regions of the world, coral reefs arealso associated with coastal zones. Coral reefs occupy less than
one tenth of one per cent of the oceans (UN 2002), yet they areamong the most biologically diverse ecosystems on the Earth,
home to more than a million spe-cies. The total area of the most
biologically productive near-surface reefs has been
estimated at around255 300 km2
(98 572 squaremiles) (Bryant et
al. 1998). About a quarter of the world’s fish
feed, repro-duce, and liveon or nearcoral reefs(Harrisonand Pearce2001). Coralreefs are a
major globalbiological
and economicresource for
both fisheries andtourism, because
they protect vulner-able coastlines from
wave action and storms(Bryant et al. 1998).
Land adjacent to the ocean isa tremendously valuable resource. Coastal zones are economically,politically, and socially critical to many nations. They are hubs of commerce and home to many major corporations and transporta-tion networks.
Coastal landscapes offer fertile soils, flat land for urban devel-opment, and sheltered, deep-water bays for harbors and ports.
Coasts are used by millions of people annually for recreation andthey support a growing tourist trade. Although coastal zones ac-count for only 20 per cent of the world’s land area, a majority of the world’s human population inhabit them. Half of the world’spopulation—some 3 000 million people—lives within 200 km(124 miles) of a coast. By 2025 that figure may double, rising tosix billion people (Cohen et al. 1997).
The oceans are a seemingly limitless and enduring resource.But they, and the coastal zones that encircle them, are currently at
risk along many fronts. In 1995, FAO reported that 52 per cent of the
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oceans’ wild fish stocks were being ex-ploited at the maximum sustainable limit,16 per cent were already overexploited,and seven per cent were depleted. Only 23 percent will be able to sustain furtherexpansion. (FAO 2005). In 24 countries for
which sufficient data were available, trawl-ing grounds encompass 8.8 million km2
(3.4 million square miles), of which about 5.2 million km2 (2 million square miles)are located on continental shelves. Thisrepresents about 57 per cent of the totalcontinental shelf area of these countries(Burke et al. 2000).
However, not all of the decline inocean fisheries may be attributed to fish-
ing. Global warming may also be partly toblame (Beaugrand et al. 2003). The deple-tion of natural fish stocks has promptedexpansion of aquaculture—the farming of fish—in many areas, a reaction to oceandegradation that does provide employment and food, but also carries with it the poten-tial for pollution and other concerns.
Case Study: Dumping of Radioactive
Waste at Sea
The Report of the United Nations Con-ference on Human Environment held inStockholm in 1972 defined the principlesfor environmental protection, specifically for the assessment and control of marinepollution. These were forwarded to anInter-Governmental Conference held inLondon later that year, where the Conven-tion on the Prevention of Marine Pollutionby Dumping of Wastes and Other Matter(also known as the London Convention of 1972) was adopted and which entered intoforce on 30 August 1975.
The contracting parties to the London
Convention agreed to promote the effec-tive control of all sources of pollution of the marine environment and to take allpracticable steps to prevent the pollutionof the ocean by dumping of waste and oth-er matter that is liable to create hazards tohuman health and to harm living resourcesand marine life. The International AtomicEnergy Agency (IAEA) was designated asthe international body that should overseematters related to the disposal of radioac-tive wastes in the ocean.
The first reported ocean disposal opera-tion of radioactive waste was carried out by the USA in 1946 in the North-East PacificOcean and the latest was carried out by theRussian Federation in 1993 in the JapanSea/East Sea. During the 48 year history of sea disposal, 14 countries have usedmore than 80 sites to dispose of approxi-mately 85 PBq (1 PBq = 1015 Bq) of radioactive waste.
The figure shows the geographical dis-tribution of disposal operations.Source: Modified from http://www.oceansatlas.org/servlet/CDSSe rvlet?status=ND0xNDExMyY3PWVuJjYxPSomNjU9a29z. Figure has been modified from http://www.oceansatlas.com/unatlas/ about/physicalandchemicalproperties/radiosp/index.htm.
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Credit: Chansareek/UNEP/Topfoto
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Ocean pollution is a growing andserious problem. Most of the wastes andcontaminants produced by human ac-tivities eventually end up in the oceans.Chemical contamination and litter exist
from the poles to the tropics and frombeaches to ocean depths. Some pollutantsare directly drained or dumped into theoceans, either intentionally, or accidentally as in the case of oil spills. Currently, theoceans must absorb an estimated 3 milliontonnes of oil spilled annually from shipsand, predominantly, from sources on land(Harrison and Pearce 2001). Other oceanpollutants first enter the atmosphere andlater settle on ocean waters. Rivers that flow into oceans carry runoff from city streets, sewage, industrial wastes, pesticidesand fertilizers from cropland, and silt fromland-clearing and construction projects.
Because of their proximity to land, coastal waters tend to have far higher concentra-tions of pollutants than the open ocean(UNEP-WCMC 2003).
Polluted waters can upset the ecologicalbalance among species in marine systems.For example, the number of poisonousalgal species identified by scientists hasnearly tripled since 1984, increasing fishkills, beach closures, and economic losses.Large parts of the Gulf of Mexico are nowconsidered biological dead zones dueto algal blooms (UN 2002). Dead zonesare coastal areas in which bottom waters(those near the ocean floor) contain very little dissolved oxygen. This conditionis called hypoxia, meaning “low oxygen”(ESA 2003). Very few organisms areable to survive in ocean dead zones (Fig-ure 3.20). The dead zone in the Gulf of
Mexico is the largest hypoxic zone in the Western Hemisphere and is also one of the largest in the world (Downing 1999;Greenhalgh 2003). In many places, thehypoxic waters of dead zones are gradually spreading out to cover larger and largerareas of ocean floor (Kempler 2000).
Marine bio-invasions have also becomemajor global environmental and eco-nomic problems. At any one time, severalthousand species are estimated to be in
Figure 3.20: The map above shows 58 reported ocean
dead zones in 1995. The oldest and most well-studiedmarine dead zones are found in the Gulf of Mexico,
the Black Sea, and the Baltic Sea. In 1995, the most severe case of hypoxia was in the Baltic Sea, in which
about one-third, or 98 800 km2 (38 000 square miles),
of the body of water was reported lifeless. Source: Modified from: http://daac.gsfc.nasa.gov/CAMPAIGN_DOCS/ OCDST/dead_zones.html
Case Study: Mississippi Dead Zone
2004
Recent reports indicate that the large regionof oxygen-depleted water—a dead zone—spreads across nearly 15 080 km2 (5 800square miles) of the Gulf of Mexico in what appears to be an annual event. NASA satellitesmonitor the health of the oceans and spot theconditions that lead to a dead zone. The pho-to (right) shows sediment-choked water fromthe Neuse River flowing out into the Gulf of
Mexico near the coast (NASA 2004h).
Source: Mississippi Dead Zone, 2004 http://www1.nasa.gov/vision/earth/environment/dead_zone.html Credit: Unknown/UNEP/NASA
Global Map of Dead Zones
Winter Summer
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The ocean is filled with life. One of the most important varieties found there are photosynthetic phytoplankton, tiny organisms that form the base of the oceanic food
web. Source: http://www1.nasa.gov/vision/earth/environment/dead_zone.html
Phytoplankton bloom off Denmark, 2004 (shown in light blue col-
or). Source: http://rapidfire.sci.gsfc.nasa.gov/gallery/?2004153-0601/Denmark.A2004153.1145.1km.jpg
Coccolithophore bloom off Brittany, France, 2004. Source: http://rapidfire.sci.gsfc.nasa.gov/gallery/?2004167-0615/France.A2004167.1335.148.1km.jpg
the ballast tanks of the world’s shippingfleet, enroute to other parts of the world.The Atlantic box jelly, believed to havebeen released in a ship’s ballast water, has
wrought ecological havoc in the Black Sea.Scientists estimate that in San FranciscoBay, a new foreign species takes hold every 14 weeks (UN 2002).
The problems are not confined toocean waters. Many coastal ecosystemshave been destroyed, and many moredegraded, often as a result of human activi-
ties. Mangroves, wetlands, seagrass beds,and coral reefs are all disappearing at analarming rate. Anywhere from 5 to 80per cent of original mangrove area in vari-ous countries has been lost, particularly in the last 50 years (Burke et al. 2000). A major contributor to this loss is the con-
version of mangroves to rice paddies andshrimp farms. With coastal regions set todouble their human populations over thenext 25 years, coastal ecosystems are com-
ing under increasing threat (Harrison andPearce 2001).
Coral reefs are particularly vulnerableto environmental change and damagefrom human activities. Nearly two thirdsof all the world’s coral reefs are deteriorat-ing (Pomerance 1999). They are dismem-bered by souvenir-seeking divers, minedfor building materials, and damaged by theanchors of cruise ships. Silt from dredging,deforestation, and urban sewage smothersand kills coral, or fosters the growth of suf-
focating and sometimes toxic algae (Har-rison and Pearce 2001). Coral reefs arealso subject to remote threats. Dust carriedaloft by storms in Africa (Figure 3.21), andthen spread across the Atlantic on prevail-ing winds, may have introduced bacterialinfections to Caribbean reefs (USGS 2003).
Global warming is also a threat to coralreefs. Higher concentrations of carbondioxide in the air make surface watersmore acidic and reduce coral growth rates
Case Study: Red Tides
Throughout the oceans, there areplaces where strong currents bringnutrient-rich deep waters to the
surface. These upwelling nutrientsnourish tiny, free-floating micro-scopic algae and other photosyn-thesizing planktonic organismscollectively known as phytoplankton.Most species of phytoplankton arenot harmful. Rather, they form thebase of the marine food web. Oc-casionally, however, phytoplanktongrow and reproduce very quick-ly—they “bloom”—and accumulateinto dense, visible patches near the
water’s surface. Some phytoplank-ton blooms are called “red tides,”especially when the species involvedcontain red pigments and so causethe water to turn pink or red when a
bloom is in progress. Phytoplanktonblooms, however, have nothing to do
with tides.
When phytoplankton die, they
sink to the ocean floor where theirremains are broken down by differ-ent kinds of bacteria. Some of thesebacteria emit hydrogen sulfide gas asa by-product of decay reactions. Thegas collects on the ocean floor untilit bubbles up toward the surface andcombines with oxygen to yield waterand sulfur. The sulfur precipitates asa white solid.
Hydrogen sulfide gas by itself istoxic to fish. But its ability to bind
with oxygen also depletes that es-sential gas from the water column. If enough oxygen is removed, deadly low-oxygen (hypoxic) conditions arecreated in the ocean.
Credit: Shoukyu/UNEP/Topfoto
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(Kleypas et al. 1999). The rise of oceantemperatures by half a degree or more inrecent decades has already placed many reefs at the top end of the temperatureranges they can tolerate without under-going “bleaching” (Harrison and Pearce2001). As corals reach the limits of theirheat tolerance, they expel symbiotic algaefrom their bodies and become “bleached.”Epidemic coral bleaching in the 1990s,
which peaked with the El Niño-induced warming of 1998, is believed to have killed
more coral in the last few years of the 20thcentury than from all human causes to date(Pearce 1999). Continued warming couldcause sea levels to rise at a rate that coralreefs cannot match.
Coastal lands have been greatly impact-ed by human activities. Fifty-one per cent of the world’s coastlines are under “moder-ate” or “high” threat from development activities (Bryant et al. 1995). Nineteen percent of all lands within 100 km (62 miles)of the coast (excluding Antarctica and
water bodies) are classified as “altered,”having been turned into agricultural orurban areas; 10 per cent are “semi-altered,”involving a mosaic of natural and altered
vegetation; and 71 per cent fall withinthe “least modified” category. A large percentage of the coastal lands in this least
modified category, however, includes many found in uninhabited areas in northernlatitudes (Burke et al. 2000).
The destruction of coastal ecosystemsand the deterioration in the quality of ocean waters, together with overexploita-
tion of resources, are seriously impactingthe survival of the ecosystems and thepeople that depend on them (SIDA n.d.).
Figure 3.21: While Saharan dust provides coral
reefs with essential nutrients like iron and copper,Saharan dust also introduces bacterial infections
to coral reefs. The image to the left is a Saharandust storm spreading out over the Mediterranean in
2004. The image to the right is of large dust plumesoff Namibia in 2004. Source: http://rapidfire.sci.gsfc.nasa.gov/gallery/?2004125-0504/Libya.A2004125.0940.1km.jpg,
http://rapidfire.sci.gsfc.nasa.gov/gallery/?2004161-0609/Na- mibia.A2004161.0930.1km.jpg
Credit: Denjiro Sato/UNEP/Topfoto
27 Mar 2004 9 Jun 2004
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Case Study: Africa’s Kipini Wildlife and
Botanical Conservancy Christian Lambrechts
The coastal region of Kenya is famous for itsnatural beauty, rich culture, diverse communi-ties, and as a recreational resource. This hasensured economic benefits for Kenya frommainly non-consumptive utilization of its natu-ral resources through tourism. Yet this develop-ment has not taken place without considerableenvironmental cost. Excessive constructionalong the coastline, uncontrolled access tomarine environments, factory fishing opera-tions, and poor planning have led to a declinein the quantity and quality of both land andmarine resources. This has been reflected inloss of biodiversity, dwindling fishstocks, and declining employment and tourism figures, although thelatter are also attributable to recent security concerns.
The Kipini Wildlife and Botani-cal Conservancy is located alongthe coast of eastern Kenya. It lies
within the Lamu and Tana Riverdistricts, but is connected eco-logically to the Ijara District. It is a well-preserved area with highbiodiversity, although few conserva-
tion projects have ever been imple-mented and current protection isinadequate with wildlife reservesonly on paper. With increasing
population pressures on the natural resourcesthere is a need for prompt action.
The Kipini Conservancy initially focuses on what was once known as Nairobi Ranch, an areaapproximately 16 000 hectares (40 000 acres)in size that is situated between the historicaltowns of Kipini, Witu and Lamu. The SwalehNguru (Sherman) family secured the landunder a freehold arrangement and has main-tained it even at a loss under livestock opera-tions. Development of the ranch is necessary, asKenya can ill afford idle land. But development is being undertaken with considerable care to
ensure adequate environmental conservation.By creating an easement on this freehold land,the Swaleh Nguru family has put it in trust forfuture generations of Kenyans as well as visitorsto the country. The conservancy will need to be
vigorously managed and will involve a transi-tion from a cattle-based ranching system to amore natural landscape populated by nativespecies. Income generation will be based onheritage value and donor support in the short term, with increasing reliance on eco-tourism.
In the future, the Kipini Conservancy is ex-pected to be expanded to include the range of critically endangered species. In a recent study funded by the Finnish Embassy, Ader’s duiker,an extremely rare mammal once thought tobe virtually extinct in Kenya, was found in thearea near the Conservancy. Expansion of theConservancy will also help to preserve highly diverse habitat corridors between the coast andthe interior and will involve surrounding com-munities in conservation efforts.
The coastal marine ecosystem adjacent tothe Conservancy is part of the Global 200 ecore-
gion. It supports a great diversity of animaland plant life and is known as a turtle nestingarea. Several species of whales and dolphins arefound in the waters offshore, as well as the glob-ally threatened dugong ( Dugong dugon ). Thepart of the Conservancy that borders the TanaRiver delta is a stop-over and wintering groundsfor many migratory bird populations. The areaalso provides habitat for threatened shorebirdsand seabirds (UNEP/GRID–Nairobi).
Credits: Christian Lambrechts/UNEP/UNEP-GRID Nairobi
Credit: Christian Lambrechts/UNEP/UNEP-GRID Nairobi
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Location of the Conservancy
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Credit: Unknown/UNEP/Topfoto
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Honduras is second only to Ecuador in the produc
and export of cultured shrimp from Latin America.
areas of the delta have been converted into farms
the cultivation of shrimp.
The rapid growth of shrimp aquaculture in Hon
duras has caused both environmental and social
COASTAL A REASGULF OF FONSECA , HONDURAS
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Credit: Unknown/UNEP/Topfoto
problems. Shrimp farmers are depriving fishers, farmers and others of access
to mangroves, estuaries and seasonal lagoons; destroying mangrove ecosys-
tems, altering the hydrology of the region, destroying the habitats of other
flora and fauna and precipitating declines in biodiversity; contributing to
degraded water quality; and exacerbating the decline in Gulf fisheries
through the indiscriminate capture of other species caught with the shrimp
post larvae that are used to stock ponds.
These two images provide a visual comparison of the increase in cov
by shrimp farms in the Gulf of Fonseca over time. It is evident from the im
ages that between 1987 and 1999, a period of about 12 years, the total a
under shrimp farming has increased tremendously.
Shrimp aquaculture in Hon-duras began in the early 1970and continued in the 1980sin the hands of both nationaland international enterprises
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Guayaquil is Ecuador’s largest city and primary sea
port. It is located on the Guayas River, which empt
into the huge Gulf of Guayaquil along the country
southern coastline. Throughout the Gulf, mangrov
have been steadily converted to shrimp aquacultu
ponds for producing farmed shrimp. In a 15-year p
COASTAL A REASGULF OF GUAYAQUIL, ECUADOR
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riod, coastal area developed for shrimp aquaculture grew by approximately
30 per cent, from 90 000 hectares (222 395 acres) in 1984 to 118 000 hectares
(291 584 acres) in 2000 (CLIRSEN 2000). Roughly 70 per cent of Ecuador’s
shrimp farming activities are located in the Gulf of Guayaquil.
In this pair of satellite images, the loss of mangroves and growth of the
aquaculture industry can be seen along the coast and in the altered dendritic
patterns (branching like a tree) of coastal waterways, especially those on
large island of Puna. Mangroves provide fish breeding grounds and wild
habitat, act as natural barriers against storm surge, and filter groundwat
Converting mangroves to aquaculture ponds has wide-reaching environ
tal implications.
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The Huang He (Yellow River) is the muddiest river o
Earth and is China’s second longest river, running 5
km (3 395 miles) from eastern Tibet to the Bohai Se
The Huang He’s yellow color is caused by its treme
dous load of sediment, composed primarily of mic
quartz, and feldspar particles. The sediment enters
COASTAL A REASHUANG HE DELTA , CHINA
Huang He Delta
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water as the river carves its way through the highly erodable loess plateau in
north-central China. (Loessial soil is called huang tu, or “yellow earth,”
in Chinese.)
Centuries of sediment deposition and dike building along the river’s
course has caused it to flow above the surrounding farmland in some places,
making flooding a critically dangerous problem. Where the Huang He flows
into the ocean, sediments are continuously deposited in the river delta,
where they gradually build up over time. Between 1979 and 2000—as th
satellite images show—the delta of the Huang He expanded dramatical
Several hundred square kilometres of newly formed land were added to
China’s coast during this period.
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The Zuiderzee is a large body of water along Holla
northeastern coast. Between 1927 and 1932, a 30
(19 miles) dam, known as the Afsluitdijk, was built
across the Zuiderzee, separating it into the outer
Waddenzee, which is open to the North Sea, and t
inner IJsselmeer (Lake IJssel) where areas of reclai
COASTAL A REASIJSSELMEER , NETHERLANDS
04
Dike
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land—called polders—are used for agriculture and as villages. Dikes built
since that time created additional polders that were drained using pumps
and, at one time, wind mills.
These images, from 1964, 1973, and 2004, show the transformation of pol-
ders into useable farming land. The 1973 image shows a partially completed
dike that, when completed allowed for the creation of the southernmost
polder visible in the 1973 image. At that time, draining of the land had b
completed and soil cultivation began. By 2004, this area of reclaimed lan
was covered with farms. The area of lighter blue water visible in the left o
the 1973 and 2004 images is the Markermeer—a polder that was created
but not drained. It forms a freshwater reservoir that acts as a buffer
against floodwaters.
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Land reclamation began in Japan’s Isahaya Bay in
1989 to separate approximately 3 000 hectares (7
acres) of tidal flats from the Ariake Sea and turn w
was Japan’s largest area of tidal lands into farmlan
As these three satellites images show, the project h
steadily progressed. In the 2001 image, the straigh
of a 7-km (4 mile) sea wall is visible separating area
COASTAL A REASISAHAYA B AY , J APAN
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of light- and dark-colored water. Behind the sea wall, tidal flats can be seen
drying as water is slowly drained away. In the 2003 image, that area has been
fully reclaimed from the sea.
The Isahaya Bay Reclamation project has been fraught with controversy.
Environmental groups have criticized the project for its destruction of wet-
land habitat. The Isahaya Bay area is known for its production of nori
(seaweed), and local farmers have complained that the reclamation proj
has negatively impacted the quality and abundance of the nori growing
the bay. The Isahaya project prompted the formation of the Japan Wetla
Action Network, a group of grassroots and national conservation organi
tions who are protesting the project and recommending that the sea wa
gates be opened to restore ecological balance.
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Snow geese migrate each spring to the shores of H
son Bay, Canada, to breed and to raise their chicks.
the past few decades, the numbers of geese desce
ing upon the Bay’s Knife River delta area have incre
substantially. Their impact on coastal vegetation c
clearly be seen in this pair of satellite images.
COASTAL A REASK NIFE R IVER DELTA , C ANADA
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In the image on the right, notice how the vegetation (green) has receded
from the shoreline north of the delta. Snow geese have overgrazed this area
and turned the shoreline into an enormous mudflat. Having denuded the
shoreline of vegetation, the geese have also moved inland in search of food
on the tundra, where overgrazed soil quickly becomes barren and develops
a crust of salt due to evaporation. The salty layer prevents the regrowth
plants, and ultimately leads to erosion. Some researchers have suggeste
lifting restrictions on the hunting of snow geese in an attempt to reduce
numbers and control the overgrazing problem. Others believe such mea
are “too little, too late.”
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which flow southeast to the South China Sea. The Mekong River is the 12th
longest in the world, flowing from western China to the Mekong Delta in
southern Vietnam. Every autumn, monsoon rains are too great for the Me-
kong to carry, and it floods a large area of Cambodia. This flood even reverses
the flow of the Tonle Sap River, northward to the Tonle Sap (“Great Lake”)
which can expand to ten times its normal size.
This pair of images show the extent of flooding associated with the t
rivers. The 2000 image was taken during a period of flooding while the 2
image was taken after the flood waters had receded. Visible also in the im
ages, especially in the south-central area of the 2001 image, are extensiv
ditches and canals that are used in irrigation.
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high population pressure and environmental hazards such as siltation, cy-
clone flooding and sea level rise, the aerial extent of the mangrove forest has
not changed significantly in the last 25 years. In fact, with improved manage-
ment, the tiger population has increased from a mere 350 in 1993 to 500-700
in 2000 and ecotourism is progressing well. However, while sufficient data is
not available, several reports suggest that forest degradation has been occur-
ring in many parts of Sundarban. The Sundarban’s mangrove forests are
becoming more vulnerable due to the significant rise of shrimp farming
the region. The increase of shrimp farming has negatively affected agric
and also contributed to the loss of mangrove forests during the past
two decades.
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14
As the city of Bangkok, Thailand, has grown, the ne
to provide food and an additional economic base
its burgeoning population has been a primary con
Parts of the Thai coastline, including those near Ba
kok, offer conditions favorable to aquaculture,
COASTAL A REASTHON BURI, THAILAND
14
Shrimp farmCredit: H. Gyde Lund/UNEP
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especially shrimp aquaculture. Over time, as these satellite images from 1978
and 2002 reveal, the mangroves that once lined the coast near Bangkok, as
well as the rice paddies that lay further inland, have been replaced by aqua-
culture ponds (blue patches inland) and urban structures (light purple). The
promotion and development of aquaculture has led to the current situation,
where farmed shrimp and fish production now exceeds that of shrimp and
fish capture by traditional methods. The development of this coastal ind
has raised environmental concerns, as extensive areas of mangroves hav
been destroyed to make way for aquaculture ponds. The challenge of ba
ancing the needs of people living in coastal areas versus the welfare of t
coastal areas themselves is ongoing, and repeated along many coastline
worldwide.
Mangrove treesCredit: H. Gyde Lund/UNEP
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16
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Credit: Laurent /UNEP/Topfoto
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18
W ater is fundamental to almost all living things on the Earth.Human health—and survival—depends on a clean andreliable supply of fresh drinking water, as well as water
for crop irrigation and sanitation (UNESCO 2000). Fresh water is water that has a very low salt content—usually less than oneper cent. Only about 2.5 per cent of all water on the planet isfresh. Of that amount, only about 0.5 per cent is surface water(found in lakes, rivers, wetlands) or accessible groundwater.
Rainfall is also a source of fresh water. But rainfall is unpredict-able and amounts vary dramatically from place to place andseason to season around the world (UNFPA 2001).
During the past century, world population has tripled.Over roughly the same period of time (1900 to 1995) wateruse worldwide has increased six-fold. Experts predict that by 2025, global water needs will increase even more, with 40 percent more water needed for cities and 20 per cent more waterfor growing crops (Paden 2000). Yet while needs increase, theamount of available fresh water is dwin-dling worldwide.
Water withdrawals fromrivers and undergroundreserves have grownby 2.5 to 3 per cent
annually since1940, signifi-cantly aheadof populationgrowth. Somuch wateris with-drawn fromseveral of the world’smajorrivers,includingthe Colo-rado River
in the UnitedStates, the NileRiver in Egypt,and the YellowRiver in China, that there is little to no wa-ter left by the time theserivers meet the sea (Postel et al. 1996). Demands on groundwaterare equally great; water tables are falling on every continent.
Over the next two decades, it is estimated that the averagesupply of water per person will drop by one-third. Annually, lackof clean drinking water can be linked to roughly 250 million cas-es of water-related disease and between 5 and 10 million deaths
worldwide. Thus, water shortages indirectly condemn millions
of people to an avoidable premature death each year.
Water shortages are also impacting global grain markets, asarid countries that rely on irrigation for crop production switchfrom growing grain to importing it (Harrison and Pearce 2001).Irrigation accounts for 70 per cent of direct water consumption
worldwide. It has been estimated that practices such as drip irri-gation and inexpensive moisture monitors could cut agricultural
water use by as much as 40 per cent (Wall 2001).
3.3 Water
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The exploitation of the world’s water resources has occurred at no smallcost to the environment. Worldwide, all major rivers have water works
that change flow regimes to some extent and therefore impact riparianecosystems. Many endemic riparian species are disappearing (Ramsar
Convention Bureau 1998), and twenty per cent of all freshwater fishare currently endangered. Few aquatic ecosystems have been as
severely impacted as wetlands, however. During the 20th cen-tury, half of the Earth’s wetland ecosystems—such as marshes,fens, swamps, and estuaries—disappeared (UNESCO 2003). Approximately 40 000 hectares (98 842 acres) of wetlands are
destroyed each year as the result of human activities (Centerfor Environmental Resource Management n.d.). Drainage for
agricultural production is the principal cause of wetland loss. At the same time that global water supplies are declining,
so is the quality of the water that remains. Water pollution isthe presence of harmful and objectionable material—suchas sewage, industrial wastes and chemicals, and run-off from
land development or agriculture—in sufficient concentrationsas to make water unfit for use (EEA 2004). Water pollution is a
serious threat to the world’s water supply.It is also a growing threat to the
oceans that cover more than70 per cent of the planet.
People have long viewedthese immense bodies
of water as limitlessdumping grounds
for wastes. Overtime, however,raw sewage,garbage, indus-trial wastes,and oil spillshave begunto overwhelmthe dilutingcapabilitiesof the oceans.
Most coastal waters are nowpolluted, often
severely (Revenga
and Mock 2000,Revenga et
al. 2000).
The 21st Century brings with it a global water
crisis. Unless corrective andconservation measures are taken, it
is estimated that by 2030 global demandsfor fresh water will exceed the supply (NSW EPA 2003, UNESCO
2000). Serious water and food security problems already exist in some developing countries and regions, and these demandurgent attention (FAO 2003).
Growing population in urban areas is exerting great pres-sure on water resources. Even if the world maintained the
pace of the 1990s in water-supply development, this wouldnot be enough to ensure that everyone had access to safedrinking water by the year 2025. The impacts of climatechange—including changes in temperature, precipitationand sea levels—are expected to have varying consequencesfor the availability of freshwater around the world. Current indications are that if climate change occurs gradually, the im-
pacts by 2025 may be minor, with some countries experiencingpositive impacts while most experience negative ones. Climate
change impacts are projected to become increasingly strong dur-ing the decades following 2025.
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20
Credit: Mario Hernan Valencia/UNEP/Topfoto
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W ATER KBG, TURKMENISTAN
The Caspian Sea, seen in this 2004 image, is the largest
inland body of water in the world, often categorized
as a large salt lake. It is salty because rivers (especially
the Volga) flow into it, but none flow out. Water leaves
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2222
through evaporation, and the dissolved salts remain. Changes in water
levels are common in the sea, resulting both from changing climatic fac-
tors and water diversion by humans. The 2004 image highlights the area
of change—the Kara-Bogaz-Gol (KBG). KBG is a large, shallow lagoon of
the Caspian Sea, normally about 18 200 km2 (7 000 square miles) and a
few metres deep. The Caspian’s changing water level has been a concern
since the 1970s. The KBG’s water flows in from the Caspian Sea, and its
fluctuations have affected the KBG dramatically.
In the 1980s, a dam blocked the KBG’s inflow, resulting in the forma-
tion of a “salt bowl” that caused widespread problems of blowing salt,
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reportedly poisoning soil, and causing health problems for people
living hundreds of kilometers downwind to the east. While the dam
was in place, not only did the KBG’s water level rapidly drop by 2 m (7
ft) or more, but the lagoon’s shallow bottom also rose 0.5 m (2 ft), due
to the accumulation of salts.
The dam was partially opened in 1985, and completely opened in
1992 when Caspian Sea water levels started to rise quickly. Today, sea
levels are more than 2.6 m (9 ft) higher than the 1978 levels and water
flows freely into the salty waters of the Kara-Bogaz-Gol.
In 1980, in response to the rapidly dropping sealevel, a dam was constructed to prevent water fromflowing into the shallow and restricted Kara-Bogaz-Gol basin, resulting in the drying up of the bay.The dam was partially opened a few years later,and completely opened in 1992 when Caspian wa-ter levels started to rise quickly. Credit: NASA Johnson Space Center
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24
W ATER A RAL SEA , K AZAKHSTAN
24
The name “ Aral Sea “ comes from the word “aral” m
ing island. The sea’s name reflects the fact that it is
vast basin that lies as an island among waterless d
erts. The Aral Sea was once the world’s fourth-larg
inland sea. Its problems began in the 1960s and 1
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with the diversion of the main rivers that feed it to provide for cotton cultiva-
tion in arid Soviet Central Asia. The surface of the Aral Sea once measured
66 100 km2 (25 521 square miles). By 1987, about 60 per cent of the Aral
Sea’s volume had been lost, its depth had declined by 14 m (45 feet), and its
salt concentration had doubled, killing the commercial fishing trade. Wind
storms became toxic, carrying fine grains of clay and salts deposited on ex-
posed sea floor. Life expectancies in the districts near the sea are signifi
lower than in surrounding areas.
The sea is now a quarter of the size it was 50 years ago and has broke
into two parts, the North Aral Sea and the South Aral Sea. Re-engineerin
along the Syr Darya River delta in the north will retain water in the North
Sea, thereby drying the South Aral Sea completely, perhaps within 15 ye
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W ATER A TATÜRK D AM, TURKEY
The power-generating station at the Atatürk Dam already pro- vides 8.9 billion kilowatt hours of electricity—roughly 22 per
cent of the electricity the country is expected to need by 2010.
Credit: Unknown/UNEP/USDA-FAS
26
Built in 1990, the Atatürk Dam on the Euphrates Ri
in southeastern Turkey is the centrepiece of the So
eastern Anatolia Project. The Atatürk Dam is the la
in a series of 22 dams and 19 hydroelectric station
built on the Euphrates and Tigris Rivers in order to
vide irrigation water and electricity to this arid reg
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Main Harran canalCredit: Unknown/UNEP/USDA-FAS
of the country. When the project’s entire system of reservoirs, power genera-
tion stations, and irrigation channels is operational (projected to occur in
2010), the irrigation of approximately 1.7 million hectares (4.2 million acres)
of land will be possible..
In these two Landsat images, acquired in 1976 and 1999, respectively, the
transformation of the region around the dam is strikingly apparent. The dam’s
reservoir reached capacity in 1992 and has supplied suffi cient water for
tion to turn a once-arid landscape into a green one. This is especially obv
in the lower right-hand corner of the 1999 image, where irrigated fields
pletely surround the town of Harran. The development of the Harran reg
could not have occurred without the Atatürk Dam project, especially sin
the town is many kilometres from the river.
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2828
The Challawa Gorge Dam, completed in 1993 on t
Challawa River, is the second-largest of the 23 dam
along rivers in Nigeria’s Hadejia-Jama’are River Bas
Though the dam has improved the water supply fo
irrigation, heavy rains cause the river to break its b
W ATER CHALLAWA GORGE D AM, NIGERIA
Vegetable crops of onions and sweet potatoes can grow in
fields maintained by irrigation.
Credit: Combs/UNEP/Africa Focus
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upstream from the dam; farmers are driven out as the rising water floods their
farms and adjoining lands. Areas downstream from the dam, on the other
hand, do not receive enough water to maintain the wetlands that border the
river. Under these conditions, the soil dries out and overgrazing occurs, which
in turn leads to wind erosion of the topsoil.
This satellite image pair gives a comparison of the area before and af
construction of the dam. The 1999 image shows the degree to which flo
ing upstream from the dam impacts the landscape, and how the lack of
downstream negatively affects riverine wetlands and cropland. The colo
the water in the flooded area is also indicative of high-sediment content
Soil turned with hand tool in northern Nigeria.
Credit: Combs/UNEP/Africa Focus
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30
For decades, heavy demands have been placed on
land-locked Dead Sea to meet the needs of growin
populations in the countries that border it. Both Is
and Jordan draw water from rivers that flow into t
Dead Sea, reducing the amount of water that wou
W ATER DEAD SEA , JORDAN
30
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naturally replenish it. The amount of area devoted to evaporation ponds for
producing salt has greatly expanded over the past three decades. The cre-
ation of salt works tends to accelerate evaporation, further contributing to
the reduction in water level. Currently, it is estimated that the water level of
the Dead Sea is dropping at a rate of about one metre (3 feet) per year.
These two images, from 1973 and 2002, reveal dramatic changes in t
Dead Sea over a period of about 30 years. Declining water levels, couple
with impoundments and land reclamation projects, have greatly increas
the amount of exposed arid land along the coastline. The near-complete
ing off of the southern part of the Sea by dry land (2002 image) reveals t
severity of water level decline.
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version of what were once farmlands to cityscapes. The city of Miami has also
expanded greatly to the southwest. The advance of urban areas westward
across the peninsula threatens the continued existence of the vast wetlands
area known as the Everglades. The Everglades ecosystem naturally filters
groundwater and helps to recharge the Biscayne Aquifer. It is also home to
a remarkable collection of plants and animals for which southern Florida is
famous. As urban areas encroach upon the Everglades, water resources
wildlife habitat are placed at serious risk. Protecting the Everglades to m
tain its essential water filtering capacity and remarkable biodiversity is p
of the mission of the Federal “Smart Growth” Task Force, which is working
better manage urban sprawl and its negative consequences.
The Florida panther.Credit: Unknown/UNEP/SFWMD
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34
The Gabcikova-Nagymoros hydraulic project on th
Danube River was started in order to generate ele
power, create an inland waterway, help manage w
supplies, and aid in the region’s economic develop
ment. The river was to be dammed and its water d
ed into a canal. Four decades after it was initiated
W ATER G ABCIKOVA , SLOVAKIA
34
rmer Danube river bottom exposed as water is redirected into the diversion canal. Credit: Peter Bardo-Déak/UNEP/WWF-DCP
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Cunovo Dam began operation in Slovakia in October 1992. The dam diverted
80 to 90 per cent of Danube River water down a diversion canal to support a
hydroelectric power station.
This pair of images from 1973 and 2000 reveal the striking changes the
massive re-channeling of river water has brought to the region. The dam
altered the hydraulic regime of the Danube River valley from a natural water-
way to a controlled patchwork of channels and islands. The diversion of
by the dam brought an end to the natural, beneficial flooding that adde
moisture and nutrients to the soil. It also reduced the ability of wetlands
marshes to filter surface water and trap sediments. Consequently, water
ity and soil nutrients levels in the region have declined. Generation of el
tricity has come with significant environmental cost.
A dam on the Danube RiverCredit: Peter Bardo-Déak/UNEP/WWF-DCP
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36
The Lesotho Highlands Water Project (LHWP) is on
the largest infrastructure projects ever undertaken
the African continent. The project is designed to d
water from Lesotho’s Maloti Mountains to South A
urban and industrial Gauteng Province. While Sou
Africa is set to benefit from an increased supply of
W ATER LESOTHO HIGHLANDS W ATER PROJECT
36
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much-needed water, Lesotho would gain through the generation of hydro-
electric power and profits from the sale of water. An 82-km (51-mile) water
transfer-and-delivery system is already in place for delivering water to South
Africa. On completion of the full project, a total of four dams will be placed in
key locations. However, many questions remain unanswered about the social
and environmental impacts the completed dams will have. The first dam in
the multi-dam scheme, called Katse, located on the Orange River, closed
gates in 1995, creating an enormous reservoir along with serious social a
environmental concerns.
These two images provide a comparison of the area before and after
completion of the Katse dam. The effects and extent of the Katse Dam ca
clearly be seen in the 2001 image.
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38
Located in Kazakhstan, Central Asia, Lake Balkhash
replenished from the Ili River catchment area, mos
which is located in northwestern China. The lake is
very important resource for the surrounding popu
tion. Water from the lake and its tributary rivers is u
W ATER L AKE B ALKHASH, K AZAKHSTAN
38
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for irrigation and both municipal and industrial purposes, including supply-
ing the water needs of the Balkhash Copper Melting Plant. Lake fish are also
an important food source. However, artificially low water prices have encour-
aged excessive use and waste of lake water. The United Nations has warned
that Lake Balkhash, which is the second largest lake in Central Asia after the
Aral Sea, could dry up if current trends are not reversed.
These two satellite images reveal an alarming drop in the lake’s wate
levels in just over twenty years. Smaller, neighboring lakes, to the southe
of Balkhash, have become detached from the main water body; they hav
dramatically decreased in size and appear to be drying up.
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40
Lake Chad, located at the junction of Nigeria, Nige
Chad, and Cameroon was once the sixth-largest la
the world. Persistent droughts have shrunk it to ab
a tenth of its former size. The lake has a large drain
basin—1.5 million km2 (0.6 million square miles)—
almost no water flows in from the dry north. NinetL AKE CHAD, A FRICA W ATER
40
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per cent of lake’s water flows in from the Chari River. The lakebed is flat and
shallow; even before the drought, the lake was no more than 5-8 m (16-26
ft) deep. Considered a deep wetland, Lake Chad was once the second largest
wetland in Africa, highly productive, and supporting a diversity of wildlife.
The lake is very responsive to changes in rainfall. When rains fail, the lake
drops rapidly because annual inflow is 20-85 per cent of the lake’s volume.
Human diversion from the lake and from the Chari River may be significa
times of low flow, but rainfall is still the determining factor in lake level.
This image set displays a continued decline in lake surface area from
22 902 km2 (8 843 square miles) in 1963 to a meager 304 km2 (117 squa
miles) in 2001.
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42
Mexico’s Lake Chapala, lying in the heart of an ex-
tremely arid region, is the country’s largest natura
The lake is one of the most important wetlands in
region and home to more than 70 endemic specie
Since the 1950s, Lake Chapala has undergone man
changes as a result of water abstraction for agricu
W ATER L AKE CHAPALA , MEXICO
42
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use both inside and outside the region and for a rapidly growing population.
The level of the lake has declined, and there have been noticeable decreases
in surrounding wetland areas as well as changes in the hydrological system
connecting various springs.
Some of these changes are visible in this pair of satellite images, including
alterations in the contours of the shoreline, obvious extensions of land near
various townships around the lake, and the appearance of remarkably la
areas of reclaimed land at the lake’s eastern end. Like all arid areas, the la
around Lake Chapala is prone to salinization. If the lake continues to shr
researchers predict both a decrease in water availability and an increase
the salt content of the region’s soil.
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2001, however, the lake all but dried up and disappeared, as can be seen in
the 2001 satellite image above.
The “dry phase” of Lake Hamoun is a striking example of how competition
for scarce water resources can transform a landscape. When droughts oc-
cur in Afghanistan, or the water in watersheds that support Lake Hamoun is
drawn down by other natural or human-induced reasons, the end result is a
dry lakebed in Iran. In addition, when the lake is dry, seasonal winds blow
sands off the exposed lakebed. The sand is swirled into huge dunes that
cover a hundred or more fishing villages along the former lakeshore. Wil
around the lake is negatively impacted and fisheries are brought to a ha
Changes in water policies and substantial rains in the region saw a retur
much of the water in Lake Hamoun by 2003.
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46
W ATER L AKE N AKURU, K ENYA
46
Lake Nakuru is located in the Eastern Rift Valley in
southwest Kenya. Lake Nakuru National Park is the
second most visited protected area in Kenya. It ho
the world’s largest concentration of flamingos, as w
as many of the animal species that make Kenya a h
valued tourism destination, including lions, leopar
Flamingos on Lake Nakuru Credit : Gray Tappan/UNEP
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rhinoceros, and water buffalo. In its total area of 188 km2 (73 square miles),
there are over 450 bird species and 56 mammal species. Recognized as a
wetland of international importance, Lake Nakuru was declared a Ramsar Site
in 1990.
The threat of land cover degradation in the catchments of the lake is likely
to increase flow fluctuation and decrease water quality. These images show
the land cover degradation in the lake’s catchment between 1973 and 2
In 2001, the Government of Kenya announced its intention to excise
km2 (136 square miles) of forest in the Eastern Mau Forest Reserve (area
white boundary in the 2000 image). As a result, most of the forest cover
upper catchment of the main rivers that feed Lake Nakuru will disappea
Vegetation around Lake NakuruCredit : Gray Tappan/UNEP
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48
Shared by Kenya, Tanzania, and Uganda, Lake Victo
is the second largest freshwater lake in the world. T
infestation of Lake Victoria by water hyacinth in the
1990s disrupted transportation and fishing, clogge
water intake pipes for municipal water, and created
habitat for disease-causing mosquitoes and other
W ATER L AKE V ICTORIA , UGANDA
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insects. This led to the initiation of the Lake Victoria Environmental Manage-
ment Project in 1994. The focus of the Project was to combat hyacinth infesta-
tions on the lake, particularly the region bordered by Uganda, which was one
of the most severely affected areas.
The 1995 image shows several water-hyacinth-choked bays: Murchison
Bay near Gaba; large parts of Gobero and Wazimenya Bays; an area outside
Buka Bay; and near Kibanga Port (yellow arrows).
Initially, water hyacinth was controlled by hand, with the plants bein
manually removed from the lake. But re-growth quickly occurred. A mo
recent control measure has been the careful introduction of natural ins
predators of water hyacinth. As the 2001 image shows, this approach se
to have been successful, as the floating weeds have disappeared from a
locations noted above.
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munities. Upstream damming as well as drainage activities in the marshlands
themselves have significantly reduced the quantity of water entering the
marshes. Together these factors have led to the collapse of the ecosystem.
Restoration of the marshlands, mainly through reflooding by breaching of
dykes and drainage canals has begun. As a result of these activities, vegeta-
tion and wildlife have returned to some parts of the marshes.
This set of images provides a synoptic illustration of the changes. Wh
the 1973 image (inset left) shows the extent of the original marshlands,
2000 image (inset right) reveals the area after being drained, with most o
wetlands having disappeared. On the other hand, the 2004 image illustr
recovery in progress with major portions in the central and western sect
having been restored to some extent.
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The Three Gorges Dam on the Chang Jiang (Yangt
River in China is one of the largest single construct
projects ever attempted on the planet. The dam w
constructed to supply approximately one-ninth of
China’s electricity—as much power as could be ge
W ATER THREE GORGES D AM, CHINA
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Credit: I Iguchi/ÜNEP/Topfoto
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rent land cover, potential land cover, current use, administration, or acombination of these criteria (Lund 2002). The United Nations Foodand Agriculture Organization (FAO), which is responsible for global
forest resource assessments, classifies “forests” using a definition that combines both land cover and use (FAO 2001). This can lead tosome lands that are without trees due to fires or clear-cutting activi-ties being classified as “forest,” while other lands that are covered
with trees, such as orchards and coffee plantations, are classifiedas agricultural land or croplands rather than forests.
Despite such caveats, it is clear that there have been significant
changes over time in the character and spatial distribution of for-ests worldwide. It is estimated that about 8 000 years ago, forestsoccupied some 6 200 million hectares (15 320 million acres), orapproximately 50 per cent, of the Earth’s land surface (Bryant et al. 1987). Today, less than 4 000 million hectares(9 884 million acres), or 28 per cent, of that total remains (FAO2001). This reduction in forest cover continues. From 1990 to2000, the global net rate of deforestation was approximately
94 000 km2 (36 294 square miles) per year. (This figure represents a
gross loss of some 123 000km2 (47 491 square miles)
of forest per year offset by a net gain, through
reforestation or
afforestation, of roughly 29 000 to30 000 km2 (11 197 to11 583 squaremiles) of for-est per year.)
Fires area naturalevent inmost ecosys-tems, includ-
ing forests.Fires are often
used to clearland on forest
margins; occa-sionally, fires are
employed to bringabout a change in land
use. Sometimes fires aresimply the outcome of increas-
ing numbers of people coming intocontact with forests. Most forestland disap-
pearance is attributable to conversion to pasture, cropland, orurbanization. Forest ecosystems are also degraded by fuel-woodcollection and the grazing of cattle and other livestock.
Gains in forest area come from afforestation projects, refor-estation, fire suppression, and the abandonment of croplands.
A major concern of conservationists is the conversion of nativeforests to tree plantations. The conversion to monocultural treeplantations is particularly harmful to the biodiversity of the origi-nal, natural forest ecosystem.
Approximately 12 per cent of the world’s forests are protected.But this protection is unevenly distributed around the globe. It isestimated that one hectare of natural, once-inaccessible forest in
Asia, South America, Africa and the former Soviet Union is lost for every 20 hectares (49 acres) of forest set aside and protected inNorth America and Europe (Sohngen et al. 1998). Just how wellthese forests are protected over ecologically significant time scales
Broadleaved evergreen
Broadleaved deciduous
Needle-leaved evergreen
Needle-leaved deciduous
Mixed forest
Swamp fores t (fresh water)
Mangrove (salt water)
Forests
Source: Global land cover 2000 (GLC 2000)
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is also a continuing issue. The historicaltrend is for people to continue to convert more and more of any forested landscapefor other uses. Often, these convertedlands end up as low-grade pasture, with theresult that forest ecosystems are destroyedfor what amounts to only transient eco-nomic or social benefit. Unfortunately, this
trend is likely to continue until either thehuman population stabilizes or demandsfor forest goods and services become sus-tainable—or both.
Whatever the future holds, many of theimages in this section show the profoundeffect that humans have had, and continueto have, on the Earth’s forests.
Forest Fire Wildfires can have both positive and nega-tive effects on the environment. In someecosystems, fires play an ecologically signifi-cant role in maintaining biogeochemicalcycles. The biological diversity of plant andanimal life in the world’s forests, prairies,and wetlands partly depends on the effectsof fire. Some plants, for example, can-
not reproduce without fire; intense heat is needed to open cones or rupture seedcoats so that seed dispersal and germina-tion can take place. Fires naturally shapemany types of ecosystems including the bo-real forests of Canada, Alaska, and Russiaand the chaparral in southern California.
In addition to “natural” fires, peoplehave used fire for thousands of years toclear land. Whether caused by nature or by people, wildfires are a significant force forenvironmental change, one that can radi-cally alter a landscape in a very short time
(see box below).The Earth’s burgeoning human popula-
tion, coupled with intensified economicdevelopment, has led to the serious deg-radation of many of the world’s forests.Degraded forests are often highly
Case Study: Rodeo-Chediski Fires
2002
On the afternoon of 18 June 2002, a fire broke out near the Rodeo Fair-grounds on the Fort Apache Reservation in Arizona. By mid-morning on20 June, the so-called Rodeo fire had expanded to 12 000 hectares (30 000acres). Meanwhile, a second blaze began burning near Chediski Peak about
24 km (15 miles) from the Rodeo fire, where a lost hiker had started a signalfire. Two days later, on 24 June, the two fires merged to encompass morethan 94 000 hectares (235 000 acres). Over the subsequent two weeks, the fireburned an additional 80 000 hectares (200 000 acres), making it the largest,most severe wildfire in Arizona. Before the blaze was brought under control,over 30 000 people were evacuated and 400 homes weredestroyed. Source: The Wilderness Society 2002
The 20 June 2002 satellite image- pictured left shows the Rodeo and
Chediski fires burning seperately. The24 June 2002 image above shows the
burned areas of the the Rodeo-Chediskifire. Areas where fires were burning
when the images were captured appearbright red; already burned areas have
a darker red coloration. Source: USGS 2002, NASA 2002
Broadleavedevergreen
Broadleaveddeciduous
Needle-leavedevergreen
Needle-leaveddeciduous
Mixed forest
Swamp forestMangrove
Source: GLC 2000
Broadleaved evergreen
Broadleaved deciduous
Needle-leaved evergreen
Needle-leaved deciduous
Mixed forest
Swamp forest (f resh water)
Mangrove (salt water)
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Credits: Unknown/UNEP/USDA Forestry Service
World Distributionof Forest Types
Chediski Fire
Rodeo Fire
20 June 2002
24 June 2002
Rodeo-Chediski
Burned Area
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susceptible to fire. Logging and large-scaleland clearing, for example, disturb themicroclimate of forest ecosystems, increas-ing their fuel load and thus the potentialintensity of resulting forest fires. Changesin the Earth’s climate, characterized by extended droughts, higher global surfacetemperatures, and more violent thun-derstorms, hurricanes and other types of severe weather, can further intensify therisk of forest fires (Remote Sensing Ser-
vices GmbH 1998). Concomitantly, firesthemselves may play an important role in
climate change by emitting both green-house gases and smoke particles (aerosols)into the atmosphere.
In 2000, more than 350 million hectares(865 million acres) of forest were burned
worldwide—an area equal to the size of
India (Northoff 2003). However, when firesweeps through a forest, many of the treesmay survive. In some cases, the fire may burn only the low-growing vegetation.
Amazon Forests and Fire
Before widespread human settlement began to encroach on the borders of South
America’s Amazon forests, there was nosuch thing as an Amazon fire season. Now,fire may pose the biggest threat to the sur-
vival of the Amazon forest ecosystem.
Slash-and-burn agriculture convertsforest to farmland, but that obvious de-struction is only the beginning. Intention-ally set fires often expand out of controland burn through the understory in areasof surrounding forest, killing, but not
completely burning small trees, vines andshrubs. The dead and dying trees col-lapse, spilling firewood and kindling to theground and creating openings in the forest canopy. Logging has a similar effect. Theintense tropical sun, previously deflectedby the green canopy, heats the forest floor,pushing fire danger even higher. In thisdamaged, fragmented landscape, the onset of the natural dry season brings with it anominous threat of fire. That threat growseven greater when El Niño-driven droughtsoccur several times per decade.
Case Study: Pará, Brazil
2004
Once extremely rare even during dry seasons, fire is now a commonoccurrence in the Amazon rain forest as people use it as a land man-agement tool. Although land management fires may not be immedi-ately hazardous, it is not uncommon for them to escape control and
become considerably more destructive. Forest fires can also impact weather, climate, human health, and natural resources.
These two satellite images show an area of the rain forest in thestate of Pará, Brazil, at the point where the Tapajós River (angling upfrom the bottom of each image) joins the Amazon River (runningacross each image). In this region, forested land is being cleared forlogging, ranching, and farming. Cleared areas are visible along the
river banks, extending into the forest. Deforest-ed areas appear light green, while undisturbedforest is dark green.
The image dated 18November 2004 reveals thelocations of a number of fires (red dots) burning indifferent parts of the forest.Roughly three weeks later,fires are still burning and theentire scene has a hazy ap-pearance, the result of smokesuspended in the air over theforest. Fires burned off andon in this region for morethan a month.Source: NOAA 2004
18 Nov 2004
7 Dec 2004
Credit: UNEP/NASA
Credits: Unknown/UNEP/NASA
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Case Study: Demilitarized Zone
The Korean Demilitarized Zone (DMZ), whichseparates the Republic of Korea(ROK) to thesouth and the Democratic People’s Republicof Korea (DPRK) to the north, representsan opportunity to preserve an environment relatively untouched by humans since the UNestablished the political buffer in 1953.
The DMZ contains five rivers, and many ecosystem types: forests, mountains, wetlands,prairies, bogs, and estuaries. In 2001, the ROK government completed a six year study of
the ecosystem in the DMZ, the 250-km-long(155-mile-long), 4-km-wide (2.5-mile-wide)no-man’s land that separates the Korean Pen-insula. It houses some of the world’s rarest spe-cies of flora and fauna. South Korean officialsbegan pushing ahead with a project to registerpart of the DMZ with UNESCO as a Trans-boundary Biosphere Reserve (TBR). The ideaof a nearly 100 000 hectares (247 105 acres)preserve in such a location is quite intriguingand unique.
Satellite images reveal significant burn scars in the DMZ.Reports state the burning is the result of military surveil-lance operations performed by both ROK and DPRK.Military officials reported 19 major fires within the DMZ in2000, burning nearly 400 km2 (154 square miles) of land.
Agreements in February 2001 to stop the burning for pres-ervation of the flora and fauna dissolved with increasedtensions in 2002. What effect this burning might have onthe ecosystem is yet unknown.
A detailed look on 13 April 2000 (upper left), reveals burnscars as black areas in the Korean DMZ. It appears that the area has been burned on both sides of the border,probably for military surveillance purposes. Areas burned
in 2000 have blended once again with the surroundinglandscape, but new burns actively clear vegetation to thenorth and east.
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Credit: Carrie E Gran/UNEP/Topfoto
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envelope that protects the butterflies from freezing on cold nights dur-
ing the five month overwintering season. Adiabatic rainfall together
with fog condensation on the fir and pine boughs provides the mois-
ture that prevents the butterflies from desiccating as the dry season
advances. A comparison of the 1986 image to the 2001 image reveals
that parts of the forests have been degraded severely. The two clo
up images serve to illustrate the most affected areas. In these ima
the unaffected forest is green in colour while the degraded area i
It is estimated that between 1984 and 1999, 38 per cent of the for
protected by two presidential decrees were degraded.
Thousands of Monarch butterflies congregate in the butterfly reserve.
Credit: Beth Allen/ UNEP/Journey North
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A RKHANGELSK , R USSIA BOREAL FOREST
The Arkhangelsk region is situated in northw
ern Russia, where its 3 000-km (1 158-mile) c
line is washed by the icy waters of three Arct
seas; the White, the Barents and the Kara. The
area’s proximity to the ocean contributed to
early settlement and subsequent developme64
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Mining activities and petroleum refineries are major sources of air pollution in northern boreal forests, including those of the Arkhangelsk region.
Credit: Fred Wohlert/UNEP/Topham
The Arkhangelsk region has suffered from severe forest degradation.
Credit: David P. Shorthouse/UNEP/Forestry Images
The Arkhangelsk region was once cloaked with dense boreal forests.
In comparing these three satellite images, however, the widespread forest
cover disturbance is obvious. In some places, large sections of the forest
have been clear-felled and the trees completely removed. Other places
show a block pattern, where sections of relatively undisturbed forest are left
between clear-felled sections to enhance reseeding and reforestation. In a
number of areas, networks of minor access roads delineate the forest cove
The region is also home to the Plesetsk Space Center and has been impac
by fire and pollution from falling rocket stages. Overall, forest cover in th
Arkhangelsk has been heavily disturbed—even within areas designated a
nature sanctuaries.
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BRITISH COLUMBIA , C ANADA TEMPERATE FOREST
Logging in British ColumbiaCredit: Rick Collins/UNEP/Topham
Temperate forests tend to be found in mid
latitude areas and are characterized by we
defined seasons with warm summers and
winters, with precipitation that is suffi cient
tree growth. The same regions of the world
which temperate forests occur are also hom66
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to large numbers of people. As a result, temperate forests constitute one
of the most altered biomes on the planet. Only scattered remnants of the
Earth’s original temperate forests remain today, some of which still contain
stands of trees that are in high demand for their valuable wood. The interior
of British Columbia is a perfect example. Logging is a major industry in British
Columbia, carried out almost exclusively in virgin forest, which is very rich in
endemic biodiversity. This pair of satellite images of the Fraser River Valle
in British Columbia shows the impact of logging and other human activit
during a period of about 25 years, from 1973-1999. The heavy exploitatio
the forest is evidenced by the “patchwork quilt” appearance that is typica
logged-over areas.
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The border between Guatemala and
Mexico runs through Mexico’s Chiapas
Forest and Guatemala’s El Peten. In this
pair of images, the border is easy to seCOUNTRY BORDER , GUATEMALA /MEXICOTROPICAL FOREST
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Iguazú National Park, located in Argentina ne
its borders with Brazil and Paraguay, contain
remnants of the highly endangered Paranae
Rain Forest. Isolated from other rain forests b
natural barriers, the Paranaense developed
a distinct and highly diverse ecosystem with
IGUAZÚ, SOUTH A MERICA SUBTROPICAL FOREST
Sparsely populated during the 1970s, thisregion has undergone major develop-ment and large areas of forest have beenconverted to agricultural lands.
Credit: John Townshend/UNEP
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Over 90 per cent of the ParanaenseForest has been converted intoagricultural fields, in which mainly soybeans and corn are grown.
Credit: John Townshend/UNEP
One of the many falls withinIgauzú National Park
Credit: Teal H.F. Smith/UNEP
thousands of species of mammals, birds, reptiles, and amphibians unique to
the area. The famous Iguazú Falls are located within the boundaries of the
National Park and are shared by Argentina and Brazil.
Between1973 and 2003, dramatic changes to the landscape occurred in
this region. In 1973 the forested area spread across the borders of the three
nations. By 2003, however, large areas of the forest in Paraguay and Braz
and smaller amounts in Argentina, had been converted to other forms o
land cover, creating a mosaic of differently colored land use areas. Note t
variation in land cover patterns among the different countries—reflectio
different land use polices and practices.
Itaipú Dam, one of the world’slargest, was built from 1973 to1982 and is a major source of electricity for both Braziland Paraguay.
Credit: IKONOS/UNEP/SpaceImaging
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Madagascar is the world’s fourth large
island and has been described as an
“alternative world” or a “world apart”
because of its unique and rare plant an
animal species. Madagascar was onceITAMPOLO, M ADAGASCAR SUBTROPICAL FOREST
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almost completely forested. But the practice of burning the forest to
clear land for dry rice cultivation has over time denuded most of the
landscape, particularly in the central highlands (tan colour in the 2001
image). Coffee production, grazing, gathering fuelwood, logging,
cattle ranching, mining and other activities also have contributed
to deforestation and land degradation. This set of satellite images
shows a narrow coastal plain near the Linta River of southwestern
Madagascar. Between 1973 and 2001, the forests in this area have
but disappeared. Remarkably, numerous endemic species still rem
in scattered forest remnants.
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74
K ISANGANI, D.R . OF THE CONGOTROPICAL FOREST Kisangani, in the Democratic Republic o
Congo, is located along the Congo Rive
the northwestern part of the country. It
city of roughly a half million people.
In these images, most of the region
Boat on the Congo RiverCredit: Lumbuenamo Raymond/UNEP
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around Kisangani is a rich green colour, indicative of dense forest cov-
er. However, directly around the city is a light green zone—evidence of
deforestation and conversion of the land to other uses. In the second
image, taken in 2001, the cleared area around the city has grown and
become consolidated; it has also spread along the rivers and the roads.
Much of the deforestation is attributed to the influx of refugees int
the country. Even the denser parts of the forest, once thought to b
impenetrable, show signs of deforestation.
Aerial view of Kisangani
Credit: Lumbuenamo Raymond/UNEP
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exports. Feeding this massive paper industry is the Finnish forest industry
– one of the most intensive in the world. As a result, Finland’s forests—in-
cluding its remaining old-growth fragments—are being exploited by
clearcutting, forest thinning, road construction, and ditching of soils. The
result is the severe and extensive fragmentation of natural habitat. While
much of Finland’s productive forest (around 62 per cent) is in the hands of
private landowners, the vast majority of its valuable old-growth forest is
owned and logged by the state. These two images show a result of this l
ging in the northeastern areas of the country. In the 1987 image, the are
has a near homogeneous forest cover (green); on the other hand, the 20
image shows only a few patches, mainly in the protected areas with con
ous forest cover. The patches of tan signify clearcut areas.
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OLYMPIC PENINSULA , UNITED STATES TEMPERATE FOREST
On the slopes and the surrounding areas o
Olympus in the Olympic Peninsula of the P
Northwest, one of the last remnants of tem
ate forests in the United States is quickly d
pearing. Between 1971 and 2002, nearly ha
million hectares (1.1 million acres), or almo78
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An alpine meadow located in Olympic National Park.
Photo Credit: Unknown/UNEP/US National Park Service
per cent of the forest covering the Peninsula, was clear-cut. That is an
area equal in size to the Olympic National Park and its five adjacent wilder-
ness areas.
The 1974 image shows the characteristic patchwork of purple and pink ar-
eas where clear-cutting has taken place. Light green patches signify regrowth
in the forest areas. On a percentage basis, forests owned by Native tribes on
the Peninsula were the most severely impacted during this period of tim
per cent of the forests on Native lands were clear-felled. In the 2000 imag
clear-cutting is obviously still continuing, as is development to the north
west, and south of the national park. There is evidence of good regrowth
trees in forest reserve areas in preparation for the next clear-felling cycle
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82
Indonesia is the second largest produc
of palm oil in the world, after Malaysia
The drive to meet the demand for palm
oil is resulting in conversion of forested
areas into palm oil plantations. These tP APUA , INDONESIA TROPICAL FOREST
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Approximately 30 per cent of the world
tropical forests are found in Brazil. In
a continuing effort to decentralize
the Brazilian population and exploit
undeveloped regions, the BrazilianR ONDÔNIA , BRAZILTROPICAL FOREST
This 1989 Landsat image shows substantial immigration tohe area between 1975-1986. The predominant “feathered”
or “fishbone” pattern illustrates the result of logging opera-ions, providing mechanized access to land resources.
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Primary land uses are cattle ranching and annual crop farm-ing. More sustainable perennial crops like coffee and cacaooccupy less than 10 per cent of the agricultural land areas.
government constructed the Cuiaba-Port Velho highway through
the province of Rondônia. Completed in 1960, the road serves as the
access route for infrastructural development in the region, previously
occupied solely by indigenous people. In 1975, the region was
still relatively pristine, with much of the forest intact. By 1989, the
distinctive fishbone pattern of forest exploitation had appeared an
by 2001 had expanded dramatically. The highway has become a m
transportation route for immigrant farmers seeking income-produ
opportunities. Migration into the area continues unabated.
Credit: Ron Levy/UNEP/Topham
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86
Mixed deciduous and evergreen needle-leaf trees
dominate the boreal forests of Sakhalin Island, jus
the eastern coast of Russia. The tremendous natur
reserves of the boreal forests serve as “carbon sink
that help to regulate global climate. Boreal forests
are also home to a unique collection of plants and
animals, including rare and endangered species su
S AKHALIN, R USSIA BOREAL FOREST
Credit: David P. Shorthouse/UNEP/Forestry Images
Boreal forests cover large parts of Alaska, Canada, Scandinavia, and western Russia.
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The deforestation rate in Côte d’Ivoire
thought to be one of the highest in tro
regions worldwide. Conservation of lar
forested areas, such as those within the
boundaries of the Tai National Park, isT AI N ATIONAL P ARK , CÔTE D’I VOIRETROPICAL FOREST
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Chile has been recently considered as one of the m
economically competitive countries in Latin Amer
Rapid growth in Chile’s production and export of
products is based on the expansion and managem
of exotic species forest plantations in the last 30 y
However, some studies have demonstrated that s V ALDIVIAN, CHILEBOREAL FOREST
90
Temporal sequence of land-use changes from agricultural land (1975) to Pinus radiata plantation (1981).
Credit: Juan Schlatter/UNEP/Istituto de Silvicultura, UACH
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expansion of forest plantation has produced a decrease in native forests in
the south-central region of the country. These two Landsat, MSS and ETM
scenes taken in 1975 and 2001, respectively, show changes in land use during
the last 30 years. Many endangered tree and shrub species have been affect-
ed by this change, which has also led to a dramatic reduction of landscape
diversity as well as goods and services from forestlands. The traditional land-
use practices of small-scale logging of native forests, livestock and agricu
have been replaced by large-scale timber production that puts endemic
endangered tree and shrub species at risk.
Mixed forest of native (Nothofagus glauca ) and exotic(Pinus radiata ) tree species.
Credit: Claudio Donoso/UNEP/Instituto de Silvicultura, UACH.
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Credit: Unknown/UNEP/Topfoto
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The success of the human race can, in many respects, be at-tributed to the development of agriculture. The ability toraise crops and therefore control a large portion of our
food supply has enabled humankind to expand and flourish as aspecies, and to grow in numbers far beyond the natural carryingcapacity of the environment. It is also through agriculture that people have brought about some of the greatest changes to theglobal environment.
The Food and Agriculture Organization of the United Na-tions defines cropland as “land used for cultivation of crops”(FAO 2002). The foods and fibers we grow on croplandsaround the world are many and diverse. They include: annualcrops such as maize, rice, cotton, wheat, and vegetables; cropsharvested after more than a year such as sugar cane, bananas,sisal, and pineapple; and perennial crops such as coffee, tea,grapes, olives, palm oil, cacao, coconuts, apples, and pears.
The total area devoted to crops worldwide increased from1 350 million hectares(3 336 million acres) in1961 to 1 510 millionhectares (3 731
million acres)in 1998, an an-nual increaseof about 0.3per cent.Most of thisexpansiontook placein develop-ing coun-tries, wherecroplandexpanded1.0 per cent annually
(Wiebe 2003). According toFAO estimates,the 1 500 millionhectares (3 706million acres) of landcurrently used for growingcrops represents just 35 percent of the 4 200 million hectares(10 378 million acres) of the world’s land judged to be suitablefor crop production. Nevertheless, much of the undevelopedarable land has marginal productivity due to costs for sustainabledevelopment and use.
Food production has more than kept pace with global popu-lation growth (WRI 2000). On average, food supplies are now 24
per cent higher per person than in 1961, and food prices are 40per cent lower. It is estimated that world population will be in-
3.5 Cropland
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creasingly better-fed until 2030, with 3 050 kilocalories (kcal) of food available person per day compared to 2 360 kcal in the mid-1960s and 2 800 kcal today. T
improvement reflects rising consumption in many developing countries, wheaverage food intake will be close to 3 000 kcal per person per day by 2030
insma 2003).
Despite increases in food production, we seem to be approaching limits of global food production capacity based on present technolog(Kendall and Pimentel 1994). At the same time, environmental damage caused by agricultural practices is continuing, and, in many parof the planet, intensifying. Worldwide, enormous areas of forests agrasslands have been converted to cropland. The conversion of naecosystems to agricultural landscapes has negatively impacted biod
versity and many other aspects of environmental health. Irrigatingfertilizing cropland has, for example, widely affected water resour
well as freshwater, coastal, and marine ecosystems. Of all human acties, agriculture consumes the greatest amount of water, accountingroughly 70 per cent of all water withdrawals worldwide. On average,
person needs about four litres of drinking water per day. Yet it takes tween 2000 and 5000 litres of water to produce the food that one per
consumes daily (FAO 2003).
Every year, water and wind erode an estima2 500 million metric tonnes of topsoi
from the world’s croplands (FAO1996). All told, about 85
per cent of the world’s aricultural lands contai
areas now degradedsome degree by er
sion, salinizationcompaction,nutrient depletion, biologicdegradation, pollution. Thextent of croland degradraises questiabout the loterm capacitagro-ecosysteto produce fo
At the same timsome of the wo
best farmland is ing withdrawn fro
food production anto other uses,
including “consumptionurbanization.
Because of its direct impact onglobal food production, damage to and lo
of arable land has become one of the most urgent problems facing t world today (Kendall and Pimentel 1994). The problem is seriously plicated by the fact that for many of the more than 1 100 million peo
who currently live in extreme poverty, economic growth based primon agricultural activities is essential to improving their lives.
Cropland mixed with tree cover
Cropland mixed with shrubs or grasses
Cultivated and managed areas
Cropland
Source: Global land cover 2000 (GLC 2000)
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Case Study: Shatt al-Arab PalmForest Destruction
1975–2002(By Hassan Partow, UNEP/DEWA/GRID-Geneva &
GRID-Sioux Falls)
Lining the 193-km-long (120-mile-long) Shatt al-Arab estuary, formed by the confluence of the Tigris and Euphrates Rivers, is the largest date palm forest in the world. Stretching backfrom the riverbanks towards the desert, dateplantations extend for distances varying from afew hundred metres to almost six kilometres (4miles). In the mid-1970s, the region counted
some 17-18 million date palms or a fifth of the world’s 90 million palm trees. By 2002, morethan 14 million, or 80 per cent, of the palms
were wiped out.
Destruction of the palm forest is due to a variety of factors. War has had the most direct impact, but salinisation and pest infestationhave also caused long-term damage. Thelivelihoods of millions of people dependent
on dates for food and income are in ruins,including a regional trade with export earningsranked second only to oil.
Impact of War
Most of the Shatt al-Arab is in Iraq. But roughtly about the last half of its course, nearits juncture with the Karun River, forms theborder between Iraq and Iran. Demarcation of the borderline has been disputed by the twocountries and was invoked as a cause in the out-break of hostilities in 1980. The conflict, whichlasted for eight years, was the longest conven-tional war of the twentieth century, claimingan estimated one million human lives and
causing extensive environmental damage. Withthe Shatt al-Arab waterway recast into a majortheatre of war, the palm forest was unavoidably caught in the prolonged and intense crossfire.The destructive power unleashed by modern
weapons in ground battles and aerial bombard-ments as well as deliberate felling reduced thepalm forest to an emaciated shadow of what it
was in its lustrous past.
Salt and Pests
Date cultivation along the banks of the Shatt al-Arab is a rare example of extensive tidalirrigation. Under the influence of the strongtwice-daily tidal action of the Gulf, upper layersof fresh estuary water are swept into the creeks,irrigating date palm groves on the flood anddraining them on the ebb.
Healthy vegetation is characterized by a distinctively strong reflectance in thenear infrared and appears red. In the infrared Landsat images above, the date palm belt skirting the Shatt al-Arab appears as a dark red hue in 1975. In 2002,
the intensity of infrared emittance in the date belt is considerably diminished;the pallid red brown indicates stressed and dead vegetation, and the replace-ment of palms by reeds and desert scrub.
Credit: Nik Wheeler/UNEP/Grid-Geneva
14 Feb 1975
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Alarming signs of salinisation in the Shatt al-Arab region began emerging in the late1960s. The situation rapidly deteriorated asdam construction intensified throughout the
Tigris-Euphrates basin, considerably reduc-ing freshwater flows and eliminating periodicflooding of the Shatt al-Arab that formerly
washed out accumulated salts. The supply andquality of water reaching the estuary dippedfurther with the desiccation of the vast Mesopo-tamian wetlands immediately above it and thediversion of marsh waters. Moreover, decreasedinland discharge has stimulated deeper seawa-ter penetration into the Shatt al-Arab, and wa-ter quality is steadily worsening due to pollutedbackflow from expanding irrigation projects inthe watershed. Despite the date palm’s high salt tolerance, excessive salinity has triggered large-scale palm dieback, with those nearest to thesea most affected but with the process continu-ing unabated inland. Finally, abandonment of date farms during the war and overall deterio-ration in palm vigour has rendered the treessusceptible to ravaging pest infestations, whichhave been particularly severe in the 1990s.
The Phoenix Factor
The date palms, whose botanical name is Phoenix dactylifera L., resemble the mythicalPhoenix bird that sprang from the ashes in that date palms are also able to regenerate from firedamage. Biotechnology may be the modernphoenix that will help replace the millions of palms that have been destroyed along the Shatt al-Arab. Iran is using a new cloning techniqueto accelerate mass date production, as dates arenaturally slow to propagate. Already, thou-sands of palm plantlets have been introduced.Biosafety regulations, however, will need to beobserved to ensure that the Iran-Iraq treasuregrove of 800 plus date varieties, representing
more than a quarter of world date diversity, isnot jeopardised by a broad dissemination of cloned palms.
Analysis of Landsat satellite imagery shows that of the 52 000 hectares (128 494acres) of date farms fringing the Shatt al-Arab in 1975 only 11 000 hectares(27 181 acres), or 21 per cent, remained in 2002. In total, war, salt and pests
have destroyed approximately 14 million palms—around 9 million in Iraq and 5million in Iran. Moreover, many of the 3-4 million remaining palms are in poorcondition.
Credit: Hassan Partow/UNEP/GRID-Geneva
27 Jan – 5 Feb 2002
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98
Rich in oil but lacking abundant water re-
sources, Saudi Arabia has used oil revenues to
adopt some of the best technologies available
for farming in arid and semi-arid environments.
One such technology is the center-pivot irriga-
tion system (CPI). In satellite images, CPI-irri-
gated fields appear as green dots.
CROPLAND A L’ ISAWIYAH, S AUDI A RABIA
This image shows the region shortly after theintroduction of center pivot irr igation.
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These three images, from 1986, 1991, and 2004, reveal the ef-
fects of this irrigation strategy in a vast desert region in Saudi Arabia
known as Wadi As-Sirhan. This region was once so barren that it could
barely support the towns Al’Isawiyah and Tubarjal that can be seen
in the upper left of each image. Following the introduction of center-
pivot irrigation, however, barren desert was gradually transformed
into a greener, food-producing landscape.
The irrigation system draws water from an ancient aquifer—some
of the water it contains may be as much as 20 000 years old. Judicious
use of water resources, and climate-appropriate technology, has in
this situation helped improve food production without being detri-
mental to the environment.
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sive greenhouse agriculture for the mass production of market pro-
duce. (Greenhouse-dominated land appears as whitish gray patches.)
In order to address increasingly complex water needs throughout
Spain, the government adopted the Spanish National Hydrological
Plan (SNHP) in 2001. Initially, this water redistribution plan involved
the construction of 118 dams and 22 water transfer projects that
would move water from parts of the country where it was relatively
abundant to more arid regions. In 2004, the Spanish government
announced it would begin exploring more environmentally friendly
water-saving technologies, such as wastewater recycling and seawa-
ter desalinization.
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0202
The unique transformation of the former USSR into
today’s modern states has had a profound effect o
the lay of the land in Ukraine. These images show a
notable difference in the agricultural land use patt
between Poland and Ukraine, probably reflecting
CROPLANDNOVOVOLYNS’K , UKRAINE
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ferent policies and approaches to land use. Of particular interest are the sizes
and patterns of the fields in the two countries; while Poland the farms are
comparably much smaller, those in Ukraine are larger.
Though the town of Novovolyns’k has not changed appreciably in size,
an apparent change in the approach to land use in Ukraine has taken place;
in the 2000 image, larger fields have been divided, following the pattern
Poland. The satellite images reveal quite vividly the contrast in land-use
tices between the individual farms of Poland and Ukraine’s former state
plan—and how the latter has changed over time.
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0404
Situated on the border between China and
North Korea, the mountain Paektu San is a sym-
bol of patriotism for the Korean people and an
embodiment of their national spirit. The moun-
tain’s rich volcanic soils and its dry, relatively
cool climate make it suitable for agriculture.
CROPLANDP AEKTU S AN, NORTH K OREA
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These two satellite images reveal the degree to which agricultural
activities have expanded on and around Paektu San, particularly on
the North Korean side of the border, where intensive land develop-
ment has served to both increase food production and underscore
North Korea’s territorial claims. In these images, green represents
natural vegetation while grayish-brown areas are bare agricultural
lands in which crops have not yet emerged from the soil. Areas of
deforestation and other types of land clearing appear pink and are
dissected by the fine lines of mountain streams. Near the center of
the more recent image there is further evidence of land-cover change
along the border between the two countries where a dam has
been constructed.
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0606
Santa Cruz is situated in Bolivia’s rich, fertile
lowlands, a region highly suitable for agriculture.
In the 1975 satellite image, the region’s forested
landscape appears as a dense, essentially un-
broken expanse of deep green that extends
CROPLANDS ANTA CRUZ, BOLIVIA
Lack of bridges and roads offered only limited access. By 1986roads were established and clearing for agriculture had beganin earnest.
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0808
The Tensas River Basin watershed lies in eastern
Louisiana and covers 272 000 hectares (672 126
acres) in the Mississippi River Alluvial Plain. His-
torically, 90 per cent of this land was forested.
Roughly 85 per cent of the forests were cleared
during the 1960s and 1970s for the planting of
CROPLANDT ENSAS R IVER B ASIN, UNITED STATES
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soybeans. Clearing of the forest has exacerbated flooding problems
and increased erosion.
As this pair of images reveals, intensive agricultural development
has continued in the Tensas River Basin over time. Croplands appear
in shades of tan; forests are green. The only remaining large tracts of
hardwood forests in the watershed are in isolated wildlife refuges and
management areas. Small forest remnants also occur on some private
lands. The contrast between the amount of land cover change that
has occurred on opposite sides of the Mississippi River in these im-
ages is striking. In the state of Mississippi, the forests remain
largely intact, possibly due to the absense of lands suitable
for cultivation.
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1010
The city of Torreón is located in the State of
Coahuila in central Mexico. Founded in 1893,
Torreón is a modern industrial city that is home
to flour mills, textile plants, iron foundries, a
rubber factory, and various other industries.
CROPLANDT ORREÓN, MEXICO
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Torreón is also situated in a rich agrarian region noted for its cotton and
wheat farms and cattle ranches.
Since the 1970s, however, there has been a significant decrease in
cropland in the Torreón region due to drought and subsequent extrac-
tion of ground water from aquifers. In 1992, the Mexican government
passed the Federal Water Law, in which the government sought to shift
responsibility for some water management rights issues from federa
local governments, or even individuals. This left farmers in a position
negotiate their own water rights. At the same time, however, prices
water for irrigation were also raised. The amount of land around Torr
on which crops are raised continues to decrease.
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1212
Egypt’s Toshka Project has transformed part of
the country’s scorching hot southern desert
into a region dotted by lush, neatly tended
vegetable plots that are supplied with water
and fertilizer by drip irrigation systems. These
images, from 1984 and 2000, document the
CROPLANDT OSHKA PROJECT , EYGPT
29 Sep 1987 13 Sep 1984
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changes and success Egypt has had in this desert reclamation project,
which was begun in the mid-1990s and aimed to double the size of
Egypt’s arable land in fifteen years’ time.
The project created four new lakes in the desert by drawing water
through a concrete-lined canal from Lake Nasser, which was formed
by damming the Nile River at Aswan. The water flows through the
canal into the Toshka Depression, where it forms the lakes visible in
the 2000 image. The faint blue-green areas visible around some of the
lakes are agricultural lands, newly created by irrigation. While provid-
ing people with new arable land on which crops can be grown, the
Toshka Project’s environmental impacts are still under study.
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Credit: Jeff Vanuga/UNEP/
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16
3.6 Grasslands
Grasslands cover roughly 40 per cent of the Earth’s land sur-face. They are, as their name implies, natural landscapes
where the dominant vegetation is grass. For purposes of this report shrublands are also considered grasslands. Grasslandstypically receive more water than deserts, but less than forestedregions. Worldwide, these ecosystems provide livelihoods fornearly 800 million people. They are also a source of forage for
livestock, wildlife habitat, and a host of other resources (Whiteet al. 2000).
Most of the world’s meat comes from animals that forageon grasslands. World meat production has nearly doubled since1975, from 116 million metric tonnes to 233 million metrictonnes in 2000 (UNEP 2002b). Grasslands and their soils storeabout one-third of the global stock of carbon in terrestrial eco-systems. These lands also are habitat for diverse and biologically important plants and animals.
Most of the world’s original grasslandsthat receive enough rainfall tosupport the growing of crops have been con-
verted to agriculturallands. In other areas,
irrigation usingimported wateror groundwa-ter has beenimplementedon tradition-al rangelandareas (SRMn.d.). Pre-cise mea-surements of area changesare difficult to come by as there is no
internationalorganizationtracking grasslandsand because of thedifficulty in identify-ing what is grasslandand what is not. How-ever, it has been estimatedthat there were over seven millionkm2 (three million square miles) of grasslandand scrubland lost between the development of agricultureand 1982 (Mathews 1983). In addition, it is known that allcroplands were developed either from forests or grasslands.In that respect, since cropland areas are expanding, it can beassumed that on the whole, grassland areas are continuing to
decline. On the other hand, large areas of tropical rainforestsare being cleared to provide pasture for livestock. Therefore,grasslands—at least in the form of pastures—may be expand-ing in some localized areas.
Worldwide, the quality of surviving grasslands is declining.This is due primarily to human-induced modifications suchas agriculture, excessive or insufficient fire, livestock grazing,fragmentation, and invasive plants and animals (White et al.2000). Invasion of the world’s grasslands by woody plants is
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among the dominant changes in the Earth’s vegetation during the last twocenturies (Polley et al. 2003). Woody plants tend to displace grasses on
grasslands. Invasion by woody plants traditionally has been attributed tothe introduction of exotic species, overgrazing, fire suppression, and
elimination of small mammals that kill woody seedlings. Fire suppres-sion in some parts of the world is resulting in the reintroduction of woody plants into grasslands that have been controlled by fire by
thousands of years. At the same time, an increase in human-madefires in other parts of the world are making it possible for grass-lands to supplant forests.
The displacement of grasses by woody plants may also berelated to the 30 per cent increase in the concentration of CO2
in the Earth’s atmosphere that has occurred over the last 200 years. Grasses use water more slowly as carbon dioxide levelsincrease. Consequently, grassland soil may retain water betterduring droughts when atmospheric carbon dioxide concentra-tions are high. Such an increase in soil water may indirectly
promote the invasion of woody plants into grassland by enhanc-ing the survival of shrub seedlings during droughts.
It is estimated that 73 per cent of the world’s grazing landhas so deteriorated that it has lost at least
25 per cent of its animal carryingcapacity (UNEP 1999b). Even
though the damage fromovergrazing is spreading,
the world’s livestockpopulation contin-
ues to grow in step with increases
in the humanpopulation,and a grow-ing demandfor meat that accompaniesincreased
wealth. As world popula-tion increasedfrom 2 500
million in1950 to 6 100
million in 2001,the world’s cattle
population grewfrom 720 million
to 1 530 million. Thenumber of sheep and
goats increased from 1 040million to 1 750 million.
With 180 million people worldwide now trying to make aliving tending 3 300 million cattle, sheep, and goats, grasslandsare under heavy pressure. As a result of overstocking and over-grazing, grasslands in much of Africa, the Middle East, Central Asia, the northern part of the Indian subcontinent, Mongolia,and much of northern China are deteriorating. While graz-
ing was once a pastoral activity that involved people moving with their herds from place to place, it has become a far moresedentary undertaking. The result is an increase in grasslanddegradation near settlements and the creation of grasslandlandscapes perforated by bore holes.
Initially, overgrazing of grasslands reduces their productiv-ity and ultimately destroys them. Worldwide, there are now 680million hectares (1 680 million acres) of degraded grasslands
(Brown 2002). Desertification is estimated to involve 3 600 mil-lion hectares (8 896 million acres) of land—roughly 25 per cent
of the world’s total surface area.
Dense
Sparse
Grasslands
Source: Global land cover 2000 (GLC 2000)
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serves, including Mara (Maasai Mara Game Reserve), Serengeti, and Tsavo, has
posed a challenge to their way of life. Diminishing income from cattle raising
and tourism activities has led to the conversion of Narok’s fertile soils into pro-
ductive agricultural lands. With World Bank estimates of US$0.75 per annum
per hectare for cattle, US$5.5 for tourism and US$218.75 for farming, the ten-
dency for grasslands conversion into to agricultural fields seems only logical
to many. By 1987, more than 27 000 hectares (66 718 acres) of land had
leased to farmers, an increase from 18 000 hectares (44 478 acres) in 197
These two images reveal the changes that have taken place in the Na
grasslands area over the past three decades. In the 1975 image, agricultu
expansion is just beginning, while the 2000 image shows the degree to w
farmlands have expanded.
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20
While much of West Africa is experiencing loss of
woodland and forest cover from expanding cultiva
tion, Senegal’s major agricultural region—the Pea
Basin—is witnessing the opposite: agricultural lan
are being abandoned, and replaced with tree-dot-
ted savannas. This pair of Landsat images shows t
GRASSLANDSPEANUT B ASIN, SENEGAL
20
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growing patchwork of savannas (greenish patches) where peanut and millet
crops once prevailed. This phenomenon is not the result of a planned land
management program. Rather, it stems from recent trends in out-migration.
The drop in world market prices for peanuts, drought, and the removal of
government agricultural subsidies have made it difficult for farmers in the
region to continue to farm. Since the 1980s, many have left in search of new
livelihoods in Senegal’s urban areas, including Darou-Mousty (upper rig
and the major centers of Touba and Dakar (not shown) as well as abroad
Those who have stayed are enjoying the benefits of a revived rotational
low system, large tracts of grazing land for a growing livestock economy
diversification into other cash crops. Hundreds of villages can be seen s
tered throughout this region (dark spots).
30 June 1983 16 November 1995 Credit: Gray Tappan/UNEP/USGS
This photo pair shows the same landscape at a 12-year interval (1983 and 1995). The view is typical of many areasin Senegal where cropland is being abandoned in favor of fallow and grazing lands. Note the regeneration of thenatural woody vegetation in the background.
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22
The impact of drought and over-grazing on the wo
vegetation of Senegal’s northeastern plateau is ev
dent both on the ground and from space. On the
one of the earliest satellite photographs ever take
northern Senegal (Corona, 26 December 1965) sho
GRASSLANDSR EVANE, SENEGAL
22
November 1983 February 1996 Credit: Gray Tappan/UNEP/
Although livestock pressure played a major role in reducing vegetation cover in local arein northeastern Senegal, the major droughts of the 1970s and 1980s had a widespread efcausing high mortality among the hardiest of tree and shrub species. This photo pair ta13 years apart, shows the dieback among Pterocarpus lucens bushes.
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ancient valleys cutting through gravelly plateaus, with extensive bushland
vegetation. In the late 1950s, a borehole was drilled deep into the underly-
ing aquifer at Revane, providing water in the dry season for livestock of the
region’s semi-nomadic pastoralists, the Fulani. By 1965, the early stages of
landscape degradation (bright areas) around Revane are visible, a result of
heavy livestock concentrations. By 1999, this badland phenomenon, ex
bated by years of drought, had spread extensively along the shallow val
slopes, leaving barren, unproductive surfaces (smooth, bright patches).
firebreak runs diagonally across the image from Revane to the northeast
Fire Break
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24
The Upper Green River Basin (UGRB) is western Wy
ming’s sagebrush steppe, a landscape punctuated
ribbons of wildlife habitat, stunning vistas, and im
tant cultural sites. The basin serves as the winter h
of large herds of pronghorn antelope and mule de
GRASSLANDSUPPER GREEN R IVER , UNITED STATES
Credit: Gary Kramer/UNEP/NRCS
24
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which migrate into the area from the highlands of Grand Teton and Yellow-
stone National Parks.
With its extraordinary reserves of oil and natural gas, the UGRB has
become a focal point for the oil and gas industry. Over 3 000 wells (black
dots in the center of the 2004 image) have been approved in the UGRB and
development is occurring at a rapid rate—one that exceeds the Bureau of
Land Management’s “reasonably foreseeable development” plan by more
than 300 per cent. The environmental impacts of this rapidly escalating o
and natural gas development are not clear, and conservationists are pres
ing for measures that will help safeguard the region’s wildlife and air and
water resources.
This aerial photograph shows the vast network of roads and well padsthat make up a portion of the Jonah natural gas field, located in Wyoming’s Upper Green River basin, 21 km (35 miles) south of the townof Pinedale. This recently drilled gas field is not coal bed methane, bushows similar high density drilling (in this case it is for gas in a “tight
sands” reservoir).
Credit: Peter Aengst/UNEP/The Wilderness Society, LightHawk, and SkyT
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26
Wyperfeld National Park in Australia’s southeastern
state of Victoria consists of some 3 000 km2 (1 158
square miles) of dry, native scrubland—classic Aus
tralian “bush.” Wyperfeld lies in the flood plain of t
Murray River, sandwiched between wet, coastal fo
and the country ’s arid interior. The park has water
GRASSLANDS W YPERFELD N ATIONAL P ARK , A USTRALIA
26
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when the river overflows its banks. Much of the park’s vegetation is mallee,
a type of shrubland dominated by several sparse, tall varieties of eucalyptus.
Over 450 species of plants, 200 species of birds, and a variety of mammals
and reptiles live within the park.
Fires set by people have been used to maintain the Australian bush for
thousands of years. Fires also occur naturally and occur in the park and sur-
rounding area nearly every year, leaving huge fire scars on the landscap
that are easily seen in satellite images (light green areas). Remote sensin
used to document the extent of burn areas, and to help land managers p
controlled burns that help maintain the native vegetation and habitat fo
tive wildlife. Wyperfeld staff currently set fuel-reduction fires along the p
edges but fight all accidental fires.
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28
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Credit: Victor Glaima/UNE
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30
A n urban area is a geographical unit of land constituting a townor city. Urbanization is the process by which large numbers of people become permanently concentrated in relatively
small areas to form towns or cities.
During the course of human history, urbanization has ac-celerated worldwide. Between 1975 and 2000, urban populationincreased from 1 500 million people to over 2 800 million, orabout 45 per cent of the world’s population (UNEP 2002b). By
2020, it is estimated that 60 per cent of the world’s population will be urban (Anon 2003).
For many people, urban living represents a better lifestyle.On average, individuals living in urban areas have higherincomes and live healthier, easier lives than their rural coun-terparts. They have greater access to clean water and sanitationthan those in rural areas. Concentrations of people also tendto strengthen infrastructures by consolidating transportationservices, utilities, and roads.
It is also true that not all urbandwellers benefit from urbanliving. In 2001, 924 mil-lion people, or rough-ly 31.6 per cent of the global urbanpopulation,lived in slums(UN Habitat n.d.). A slumhouseholdis one in
which agroup of individu-als livingunder thesame roof lack oneor more
fundamentalnecessities,including accessto clean water,access to sanitation,secure tenure, dura-bility of housing, andsufficient living area (Warah2003). In the next thirty years,as many as 2 000 million people will beliving in urban slums unless substantial policy changes are put into place.
Wherever people are concentrated in large numbers, as they are in urban areas, the risk of disease and other health concernshave the potential to become extremely urgent issues. Overcrowd-
ing fosters epidemics of tuberculosis, influenza, and many othercommunicable diseases (Myers and Kent 1995). Urban areas alsotend to be polluted. According to some estimates, industrializedcountries exhaust 3 146 kg (6 936 lbs) of fossil fuels and produce200 kg (440 lbs) of air pollutants every year. Fossil fuel use addsboth pollutants and greenhouse gases to the atmosphere, thelatter of which contribute to global warming. Temperatures inheavily urbanized areas may be 0.6-1.3ºC (1.1-2.3ºF) warmer than
3.7 Urban Areas
30
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in rural areas. Higher temperatures, in turn, make cities incubatofor smog (WRI 2000).
Urban populations are growing rapidly worldwide. As urbanareas expand, they often encroach into agricultural lands. Urbanexpansion into agricultural areas in developing countries results the conversion of nearly 500 000 hectares (1 235 526 acres) of ar-able land annually. However, urban and developed areas currentlcover only about two to four per cent of the Earth’s land surface(Wiebe 2003). As a result, some researchers argue that land lost turbanization will not threaten global food production in the foreseeable future (Rosegrant et al. 2001). Nevertheless, urban expansion frequently takes prime agricultural land out of production,
making it increasingly necessary to use marginal lands for croplanand pastures.
Perhaps the greatest impact of urbanization is on the environment. Cities use some 75 per cent of the world’s resources anddischarge similar amounts of waste, negatively impacting the heaof local and global environments (Giradet 1995). By the end of th1990s, people in developed countries produced from 300-800 kg(661 - 1 764 lbs)of waste per person per year (UN-HABITAT 2005The growth of urban populations in most countries of the world
has led to the creation of “supercities”—urban areas where
the original core city habecome part of an
agglomeration thtakes in neighb
ing towns, newsuburbs, dormitory townor shanty settlemenIncreasingsuper citieare becoming powerful economic, socialand cultur
entities.
One pos
tive aspect of urbanization isthat urban dwell
ers tend to havefewer children and
help limit populationgrowth. While badly run
urban sectors can be seriouproblems for a country, a well-ru
urban sector can help ensure nationalprosperity. Well-planned cities can capitalize on high populationdensities to minimize resource use and energy consumption andCO2 emissions—for example, by developing mass transit systems.Some cities are investing large sums in recycling and compostingpart of ambitious waste-management programs. Many cities main
tain large areas of productive agricultural land amid highways anhigh-rises (Harrison and Pearce 2001).
Urban areas / artificial surfaces
Source: Global land cover 2000 (GLC 2000)
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32
The Gambia is a small—11 295 km2 (4 361 square
miles)—country in West Africa. It is surrounded by
Senegal on all sides except on its coast. The capita
city of Banjul lies at the end of a small peninsula th
protrudes into the Atlantic Ocean.
URBAN A REASB ANJUL, THE G AMBIA
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The country’s population is increasing at a rate of about 4.2 per cent an-
nually. For the past three decades, western Gambia has undergone consider-
able urban growth, particularly in Banjul and some of its neighboring cities,
including Serekunda, Bakau, Sukuta, and Brikama. The population of the
greater Banjul area, for example, more than tripled during this time. These
two satellite images, taken in 1973 and 1999 respectively, show this urban
sprawl and its impact. Urban growth and the accompanying expansion
cropland around urban areas have led to a significant decline in woodla
areas (dark green). The Abuko Nature Reserve, located in the center of th
images, was once surrounded by woodlands. I t now stands out as an iso
patch of green in an otherwise developed landscape.
Credit: David McKee/UNEP/Gambia Tourist Support
The mangroves that lie on the northeaedge of Banjul have largely escaped de-s truction, as urban development has m
progressed westward. Increasing population and human encroachment remain threat to the mangroves .
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34
Beijing, the capital city of the People’s Republic of
China, is located in the country ’s northeastern cor
in the transition zone between the Inner Mongolia
Plateau and the North China Plain. It is a city that h
undergone tremendous change and explosive urb
growth, since the start of economic reforms in 197BEIJING, CHINA
URBAN A REAS
Credit: Simon Tsuo/UNEP/NREF
Market vendors selling fruits on aBeijing street.
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The left-hand satellite image shows Beijing in 1978, just prior to the
reforms. The light blue-gray area in the center of the image is the urban
landscape of the city. The hills to the west are covered with deciduous forest,
which appears green. The agricultural lands that lie around the city appear as
muted red, orange, and golden yellow, depending on the crop (rice, win-
ter wheat, or vegetables) and its stage of development. Beijing’s explosiv
growth is very obvious in the 2000 image. The city has expanded from its
original center in all directions. Prime agricultural lands that once lay out
the city are now suburbs dominated by institutional, industrial, and resid
tial buildings. In 2000, Beijing’s population was 13 million.
Credit: Law Chun Wah/UNEP/Topha
Home to 13 mil l ion people , Bei j ing has experienced verapid urban growth in the past several decades.
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36
Inaugurated on 21 April 1960, Brazil’s new capital o
Brasilia began with a population of 140 000 and a
ter plan for carefully controlled growth and develo
ment that would limit the city to 500 000. Urban p
ner Lucio Costa and architect Oscar Niemeyer inte
that every element—from the layout of the resideBRASILIA , BRAZILURBAN A REAS
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and administrative districts to the symmetry of the buildings themselves—
should act in harmony with the city ’s overall design. This consisted of a bird-
shaped core with residential areas situated between the encircling “arms” of
Lake Paranoá. The city was a landmark in town planning and was recognized
as a World Heritage site in 1987.
As these images reveal, unplanned urban developments arose at Bras
fringes resulting in a collection of urban “satellites” around the city. Sever
new reservoirs have been constructed since Brasilia’s birth, but the Natio
Park of Brasilia stands out as a densely vegetated expanse of dark green t
has remained relatively unchanged. In 1970, the population of Brasilia an
satellites was roughly 500 000. The population now exceeds 2 000 000.
Credit: Unknown/UNEP/Topham
New housing replaces natural forest.
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38
India occupies only two per cent of the world’s tot
landmass. Yet it is home to 15 per cent of the worl
total population. Urban growth is characteristic of
most Indian cities, with that of Delhi being especia
dramatic, as these satellite images from 1977 and
clearly show.DELHI, INDIA URBAN A REAS
Credit: UNEP/Space Imaging Ikonos satellite image of Delhi
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In 1975, Delhi had a population of 4.4 million people or 3.3 per cent of
India’s entire urban population. In 2000, the city had 12.4 million inhabitants,
or more than 4.5 per cent of the country’s urban population. Of the world’s 30
largest urban agglomerations, Delhi ranked 24th in 1975 and tenth in 2000.
By 2015, Delhi’s population is expected to be 20.9 million.
In these images, urban areas appear in shades of gray and purple. Gro
is especially noticeable in the suburbs and areas surrounding Delhi such
Ghaziabad, Faridabad, and Gurgaon. Rapid urbanization has placed trem
dous pressure on land and water resources in and around Delhi.
Credit: Brassier Rene/UNEP/Topham
Aerial view of Old Delhi
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40
Dhaka, the capital of Bangladesh, has undergone p
nomenal growth since the country gained indepen
dence in 1971. It has grown from a city of 2.5 millio
inhabitants to one with a population of more than
million. This increase represents an average populaDHAKA , B ANGLADESHURBAN A REAS
Credit: Jim Welch/UNEP/NREL
Vegetable vend or in Dhaka
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growth rate of about eight per cent annually. Dhaka is one of the poorest and
most densely populated cities on the planet, with 6 545 people per
square kilometre.
Following independence, urban areas expanded rapidly as they sought
to become hubs of production and modernization. In the process, land use
changed dramatically, as these images from 1977 and 2000 reveal. Dhaka is
visible in the central portion of each image along the Turag River. Green
represent forests and agricultural lands. White spots are planned areas o
infrastructure. Urban areas are light purple. The 2000 image shows how,
time, lowlands and agricultural lands have been converted to urban area
where Dhaka has expanded to the north.
Credit: UNEP/Space Imaging Ikonos satellite image of Dhaka
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42
Las Vegas is the fastest growing metropolitan area
the United States. Its growth was fairly slow during
first half of the 20th century, but as the gaming an
tourism industry blossomed the population increa
more rapidly. In 1950, Las Vegas was home to 24 6
people. Today, the population of the Las Vegas ValL AS V EGAS, UNITED STATESURBAN A REAS
A girl waters the yard in Clark County, Nevada.Credit: Lynn Betts/UNEP/USDA-NRCS
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tops one million, not including the tourists. According to one estimate, it may
double by 2015. This population growth has put a strain on water supplies.
Satellite imagery of Las Vegas provides a dramatic illustration of the spa-
tial patterns and rates of change resulting from the city’s urban sprawl. Las
Vegas is shown in the central portion of these images from 1973 and 2000.
Note the profound modifications to the landscape—specifically the prolifera-
tion of asphalt and concrete roads and other infrastructure, along with t
displacement of the few vegetated lands. By 2000, Las Vegas’ growth had
sprawled in every direction, with the greatest expansion to the northwe
and southeast. As the city expanded, several new transportation networ
emerged to serve the city’s inhabitants.
Credit: Lynn Betts/UNEP/USDA-NRCS
New housing and a golf
course in Nevada replacenatural desert .
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44
Mexico City is one of the fastest growing megalop
cities in the world. These satellite images show the
transformation Mexico City underwent between 1
and 2000. Areas of urban infrastructure appear as
MEXICO CITY , MEXICO
URBAN A REAS
1910 1929 1941 1959 1970
The red fill shows the historical urban boundaries of Mexico City.
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shades of purple while natural vegetation is shown in green. In 1973 Mexico
City had a population of about 9 million. In the ensuing years, the city ex-
panded into surrounding areas. The forests in the mountains west and south
of the city suffered significant deforestation as the urban sprawl progressed.
By 1986, Mexico City’s population had soared to 14 million. In 1999, Mex
City had a population of 17.9 million, making it the second largest metro
politan area in the world behind Tokyo, Japan. The Mexican megalopolis
expected to reach 20 million in the next few years.
Credit: CentroGeo/José de Jesús Campos Enrîquez
A street view of historical Mexico City
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46
Midrand is located approximately halfway betwee
major urban centers of Johannesburg and Pretoria
South Africa. The major highway that connects the
two large cities dissects the city of Midrand into ea
MIDRAND, SOUTH A FRICA URBAN A REAS
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and west halves. Since 1978, the city has been rapidly transformed as a result
of population growth, agriculture, mining, and industry.
In the 1978 image, the area surrounding Midrand consists largely of
agricultural lands and rural residential zones, with some evidence of commer-
cial development. The 2002 image reveals high-density urban development
throughout. Rapid growth of Midrand’s economy is expected to continu
Current development trends and population growth rates indicate that i
fective environmental management strategies are not adopted soon, sig
cant deterioration in the quality of the environment can be expected.
Credit: Stephan Volz/UNEP/Afr ica Focus
Downtown Johannesburg
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48
Moskva—Russia’s capital city and its political and
economic heart—sits on the far eastern end of Eu
roughly 1 300 km (815 miles) west of the Ural Mou
tains and the Asian continent. The Moskva (Mosco
River winds through the city, and the Kremlin, the MOSKVA , R USSIA URBAN A REAS
Credit: UNEP/Space Imaging Ikonos satellite image of the Kremlin
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of the Russian government, lies at its center. With a population close to 9 mil-
lion and an area of 1 035 km2 (405 square miles), Moskva is believed to be the
largest of all European cities.
These two images show the urban expansion Moskva experienced during
the last 25 years of the 20th century. The blue-gray patches are urban areas.
The light green areas surrounding the city are farms while the brown are
are regions of sparse vegetation
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to roughly 2 million inhabitants. The entire Paris metropolitan area, however,
includes more than 11 million people.
Lying roughly 160 km (100 miles) southeast of the English Channel in
northern France, Paris is considered by many to be one of the most beautiful
cities in the world. In the images above, the Seine River can be seen winding
its way through the heart of the city. Urban areas appear gray and purple
patchwork of green, brown, tan and yellow around the city is primarily fa
land. Note how the city has expanded in the years between 1987 and 20
reaching ever-further into the surrounding rural areas.
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52
Santiago, the capital of Chile, is home to more than
one-third of the country’s total population of 15 m
lion. Santiago’s rapid growth is part of a national tr
but it is also a reflection of the large numbers of im
grants who are moving into the city.S ANTIAGO, CHILE
URBAN A REAS
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Santiago’s population growth has led to a horizontal expansion of the
city, principally towards the south and southeast. Chilean urban scholars
speak of this expansion as the “urban stain” that continually exceeds and
expands the limits of the Metropolitan Region of Santiago (MRS) while in-
corporating previously rural areas into it. Characteristics of Santiago’s urba
sprawl are haphazard growth, low-density housing, poor transportation,
and air pollution. In the time frame illustrated by these images, Santiago’s
population has nearly doubled.
Credit: Robb Campbell/UNEP/Earthshots
Downtown Santiago, Chile
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54
Australia is the sixth largest country in the world. I
is roughly the same size as the conterminous Unit
States and 50 per cent larger than Europe. Yet Aust
has the lowest population density of any country i
the world. With 4 million inhabitants, Sydney isSYDNEY , A USTRALIA URBAN A REAS
Credit: DTCreations/UNEP/Morguefile
Sydney Opera House is one of the architectural wonders of the world, with its design and construc-t ion involving countless innovative des ign ideas andconstruction techniques .
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Australia’s largest city. It is also the capital of New South Wales, the country’s
most densely populated state. Sydney is bounded by the Pacific Ocean to the
east, national parks and deep-water inlets to the north and south, and the
spectacular Blue Mountains far to the west. These natural boundaries have
influenced Sydney’s urban growth patterns. Over the past several decades,
the city’s expansion has been largely westward toward the Blue Mounta
as can be seen in these two satellite images. As suburbs sprawl into bush
they become vulnerable to summer bush fires.
Credit: Kevin Connors/UNEP/Morguefile
A marina in Sydney, Australia
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These three satellite images, from 1976, 1989, and 2002, document some of
the major changes.
Urban areas appear as shades of grey. Darker patches south of the city, vis-
ible in both the 1976 and 1989 images, represent grasslands that have been
converted to agricultural fields. Bright green areas are planted croplands. In
the 2002 image, urban expansion is especially notable. The irregular bro
patch in the upper far right of this image, south of Al Hamidiyan, is perha
the last remaining vestige of natural vegetation in the Tripoli region.
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58
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Credit: Andrew Magor/UNEP/Topfoto
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60
Of all the terrestrial biomes, tun-
dra is the coldest. Tundra comes
from the Finnish word tunturia ,
which means treeless plain (Pullen 1996).
There are two distinct types of tundra: the
vast Arctic tundra and high-altitude alpine
tundra on mountains.
Arctic tundra is located in the Northern
Hemisphere on lands encircling the North
Pole and extending south to the conifer-
ous boreal forests of the taiga and covering
approximately 5.6 million km2 (2 million
square miles) Wookey 2002). Arctic tundra
is characterized by cold, desert-like condi-
tions. Although somewhat variable from
place to place, precipitation on the Arctic
tundra, including melted snow, is roughly
15 to 25 cm (6 to 10 inches) annually. Theaverage winter temperature is -34° C (-30°
F); the average summer temperature is 3 to
12° C (37 to 54° F). Winters are long and
summers brief, with the growing season
only 50 to 60 days long. During summer,
only the top few centimeters of the soil
thaw. Beneath the surface is a layer of
permanently frozen subsoil called per-
mafrost. Because the topsoil is so shallow
and underlaid by permafrost, it becomes
quickly saturated with water. Lakes, ponds,
and bogs dot the surface of the Arctic tun-
dra throughout the brief summer months,
providing moisture for plants and
nesting and feeding habitats for huge
numbers of waterfowl and other
animals (Pullen 1996).
Alpine tundra is found on mountains
throughout the world, at high altitudes—
above the tree line—where conditions are
too cold and too dry for trees to grow. The
growing season in alpine tundra is approxi-
mately 180 days. Nighttime temperatures
are usually below freezing. Unlike soils in
the Arctic tundra, soils in alpine tundra areusually well-drained (Pullen 1996). Alpine
tundra is also characterized by relatively
high biodiversity.
The Earth’s polar regions are high-lati-
tude zones above the Arctic Circle in the
Northern Hemisphere and the Antarctic
Circle in the Southern Hemisphere (EEA
n.d.). Although similar in many ways, the
two polar regions differ in that the Arctic
is a frozen ocean surrounded by land,
whereas the Antarctic is a frozen continent
surrounded by ocean.
Most of the world’s fresh water is
locked up in polar ice caps. Large glaciers
and ice sheets cover Arctic islands and
Greenland in the north and the conti-
nent of Antarctica in the south. Where ice
sheets and glaciers meet the ocean, huge
chunks of ice continually break off, in a
process known as calving, to give birth to
icebergs. Icebergs are found in both Arctic
and Antarctic polar oceans. In the north,
most icebergs are calved from ice sheets
along the western coast of Greenland. Inthe south, the vast ice sheets and glaciers
that cover Antarctica give rise to icebergs
in polar seas.
The Earth’s tundra and polar regions
are unique and vital parts of the global
environment. They are the world’s least
3.8 Tundra and Polar Regions
Credit: Brendan C. Fri/UNEP/Topfoto
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populated regions. Antarctica has no
permanent residents. The Arctic has ap-
proximately 3.7 million inhabitants from
eight countries. Sparsely populated and
relatively undisturbed, tundra and polar
regions therefore contain the world’s larg-
est remaining wilderness areas. They also
possess a surprising range of natural re-
sources, from marine life to oil and gas. Yet
despite their rugged appearance, tundra
and polar regions are fragile ecosystemsthat are extremely sensitive to the effects
of resource exploitation. Managing these
regions and their resources effectively
places huge demands on both technical
and political capacities (SPRI n.d.).
Tundra and polar regions also ex-
ert a profound effect on global climate.
Variations in the extent of sea ice, for
example, affect the Earth’s surface radia-
tion balance by changing average surface
albedo(albedo is the fraction of sunlight
reflected). During the peak of the last
Ice Age, one-third of the Earth’s land
surface was covered by thick sheets of ice
that extended from polar regions toward
the equator. The high albedo of these ice
sheets reflected a great deal of sunlight
out into space, which cooled the Earth
and allowed the ice sheets to grow. Large
changes in sea ice extent are also thought to influence deep-ocean convection and
global ocean currents (Jezek 1995).
Many climate and biogeochemical
studies indicate that carbon cycling in the
Arctic tundra and boreal forests strongly
influences global climate as well. Cold tun-
dra soils contain huge amounts of stored
organic carbon. They are known sinks for
atmospheric CO2 through the accumula-
tion of peat, and are significant sources of
CH4 as a result of anaerobic decomposi-
tion (Christensen n.d.).
While tundra and polar regions play a
major role in shaping the Earth’s climate,
they also are highly sensitive ecosystems
that have the potential to be profoundly
affected by changes in the Earth’s climate
(NRDC 2004). Nearly all climate mod-
els indicate that environmental changes
brought about by global warming are
expected to be greater in tundra and polar
regions than for most other places onEarth. In that respect, tundra and polar
regions form a sort of early warning system
for climate change and its effects on the
planet and its inhabitants. The monitoring
of high-latitude and high-altitude eco-
systems, then, represents a way to detect
early signs of regional and global climate
change. The advance or retreat of
glaciers, ice sheets, and sea ice has been
given particular attention by climate
change researchers.
A rapid warming trend in the Arcticpolar region over the last 25 years has
dramatically reduced the region’s sea ice.
Scientists have been monitoring ongoing
changes in Arctic sea ice for decades, both
firsthand through fieldwork and remotely
through the use of satellite imagery. In
2002, the extent of multi-year Arctic sea
ice was the lowest on record since satel-
lite observations began in 1973. There
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Map of the Arctic Source: Modified from http://www.lib.utexas.edu/maps/islands_oceans_poles/arctic_region_pol02.jpg
Credit: Budd Christman/UNEP/NOAA
Arctic Region
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62
was only slightly more sea ice present in
2003. According to one study, perennial
sea ice—sea ice that survives the summer
and remains year round—is melting at the
alarming rate of 9 per cent per decade
(NASA 2003d). If this trend continues,
Arctic sea ice may be gone by the
year 2100.
Researchers also documented tem-
perature increases in different regions
within and near the Arctic Circle, north
of 66º. Average temperatures increased
by 0.3ºC (0.5ºF) per decade over sea ice
and by 0.5ºC (0.9ºF) per decade over the
northernmost land areas of Europe and
Asia. Temperatures over northern North
America experienced the highest regional
warming, increasing by 1.06ºC (1.9ºF) per
decade. Greenland cooled by less than
one-tenth of a degree C per decade. The
cooling found over Greenland was mainly
at high elevations, while warming trends
were observed around its periphery. These
results are consistent with a National Snow
Pancake ice in the Ross Sea, Antarctica Source: Michael Van Woert/UNEP/NOAA
Case Study: Arctic SeasThe extent of Arctic sea ice in September–the end of the summer melt period–is themost valuable indicator of the state of theice cover. On average, sea ice in Septembercovers an area of about seven million km2,an area roughtly equal in size to the conti-
nent of Australia.In the images above, the Sea Ice Con-
centration Anomaly scale indicates theper cent by which the local sea ice extent
differs above or below the average for theperiod 1979-2000. The median ice edgefor 1979-2000 is indicated by the blackouter line. In 2002, total September iceextent was 15 per cent below this average.This represents a reduction equivalent toan area roughly twice the size of Texas or
Iraq. From caparisons with records prior tothe satellite era, this was probably the least amount of sea ice that had covered the
Arctic over the past 50 years.
Quite often, a “low” ice year is followedby recovery the next year. However, Sep-tember of 2003 was also extreme, with 12per cent less ice extent than average. Cacu-lations performed for 30 September 2004show a sea ice extent loss of 13.4 per cent,especially pronounced north of Alaska andeastern Siberia. Source: NSIDC
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and Ice Data Center study that found
record loss of sea ice around Greenland’s
periphery in 2002 (NSIDC n.d.).
As sea ice melts, Arctic waters warm.
Less ice means more heat gain by polar wa-
ters, which creates a positive feedback lead-
ing to further ice melting and increased
warming. The loss of Arctic sea ice, andthe warming of Arctic polar waters, have
enormous implications for both regional
and global climate patterns. One major
concern is that the disappearance of Arctic
sea ice may cause changes in ocean circula-
tion leading to unexpected and rapid shifts
in climate worldwide (SPRI n.d.).
Over the past 30 years, Antarctic ice has
also undergone changes. Ice sheets and
glacier tongues are among the most dy-
namic and changeable features along the
coastal regions of Antarctica. Seaward of a
line where these masses of ice are ground-
ed, the floating ice margins are subject to
frequent and large calving events. These
events lead to annual and decadal changes
in the position of ice edge varying from
several to many kilometres.
Yet ice events are also occurring in
Antarctica that appear to be out of the or-
dinary. Along the Antarctic Peninsula, for
instance, the Wordie Ice Shelf has practi-
cally disappeared. In 2002, a section of the
Larsen B Ice Shelf collapsed—the largest
such event in the last 30 years.
In other parts of Antarctica, however,
ice cover has actually increased (UPI
2003). What is happening with the vast West Antarctic ice sheet is not yet clear.
Some studies seem to indicate that it is get-
ting thicker (NCPPR n.d.). Other studies
indicate that this mammoth ice sheet is
shrinking in size. If the West Antarctic ice
sheet melts, global sea levels would rise by
many metres. Such a change would severe-
ly impact densely populated coastal regions
around the world, forcing people to move
to higher elevations.
Although the details may be still un-
clear, there is no doubt that the Earth’s
tundra and polar regions are undergoing
many changes. Some are related to climate
change and long-distance pollution. Some
are the result of on-site human activities.
On a positive note, many of the human-in-
duced environmental threats in the Arctic
have not yet occurred in the largely un-
populated Antarctic (Harrison and Pearce
2001). Activities in Antarctica are carried
out under the Antarctic Treaty, a model of
international cooperation. In the Arctic,
the common needs of indigenous peoples
living in remote areas are addressedthrough the Arctic Council and other
circumpolar institutions. Thus, the polar
regions offer hope that nations can cooper-
ate in addressing the changes taking places
in these and other parts of the
world (SPRI n.d).
Case Study: Ninnis Glacier, Antarctica2000To better understand the Antarctic Ice Sheet’spotential response to global climate changeand its effect on global sea level, it is important to detect and monitor the calving of large ice-bergs. The series of images shown here depect the 2000 disintegration of the Ninnis Glaciertongue into two sections. Each image is asub-section of a SCANSAR scene of the NinnisGlacier Tongue region.
22 January 2000. This image captures the Nin-nis Glacier Tongue region soon after the initialcalving. The resultant iceberg (sections A andB) had an area of approximately 900 km2 (347square miles). NOTE: Purple dots indicate thearea where the iceberg broke away from theglacier.
5 February 2000. Roughly two week aftercalving, the iceberg split into two sections (A and B). When this image was taken Berg A had drifted 20 km (about 12.5 miles) to the
west, Berg B had drifted to the northeast, anda smaller section (C) remained grounded infront of the Ninnis Glacier.
20 February 2000. At this point Bergs A andB had almost totally separated, rotated coun-terclockwise, and drifted to the north. Notethat both sections are now well away from theNinnis Glacier.Source: USGS 1999; Schmidt 2000
Between 2000 and 2002, scientists observed theformation of a crack in the Ward Hunt Ice Shelf on the northern shore of Canada’s EllesmereIsland. The crack allowed the waters of a rarefreshwater Arctic lake to empty into the ArcticOcean. Rising temperatures also brought about the thinning of this 3,000-year-old shelf, whichis the Arctic’s largest. Credit: V. Sahanatien/UNEP/Parks Canada
Images courtesy of Dr. Rob Massom, Antarctic CRC © 2000 Canadian Space Agency
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64
Mountain peak in the Himalayas Credit: Unknown/UNEP/Freefoto.com
Gangotri Glacier is situated in the Uttar KashiDistrict of Garhwal Himalaya, northern In-dia. With its tributary glaciers, it is one of thelargest glaciers in the Himalayas. It has beenreceding since 1780, although studies showits retreat quickened after 1971. It is currently 30.2 km (18.8 miles) long and between 0.5and 2.5 km (0.3 and 1.6 miles) wide. The bluecontour lines drawn in the image show therecession of the glacier’s terminus over time.They are approximate, especially for the earlier
years. Over the last 25 years, Gangotri Glacierhas retreated more than 850 m (2 788 ft) withan accelerated recession of 76 m (249 ft) from1996 to 1999 alone. The retreat is an alarmingsign of global warming, which will impact localcommunities. Glaciers play an important rolein storing winter rainfall, regulating water sup-ply through the year, reducing floods, shapinglandforms, and redistributing sediments.Source: NASA 2004j
Case Study: Recession of Gangotri Glacier1780-2001
Credit: NASA 2004
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Case Study: Drygalski Ice TongueFebruary 2005
The Drygalski ice tongue is located on theScott Coast, in the northern McMurdo Soundof Antarctica’s Ross Dependency, 240 km (149miles) north of Ross Island. It stretches 70 km(43 miles) out to sea from the David Glacier,reaching the sea from a valley in the Prince
Albert Mountains of Victoria Land.
The ice tongue was discovered in 1902 by Robert Falcon Scott, and is thought to be at least 4 000 years old.
This image, collected by the AdvancedSynthetic Aperture Radar on the EuropeanSpace Agency’s ENVISAT satellite, shows theDavid Glacier on the 1 831-metre-high (6 007-
feet-high) Mt. Joyce. As ice piles on the glacier,it slides under its own weight to the ocean.The ice doesn’t break up when it reaches theocean; rather, it floats, forming a long tongueof ice. The floating end of the David Glacier isthe Drygalski Ice Tongue.
This floating spit of ice was recently men-aced by the B-15A iceberg, a 120-km-long(74-mile-long) giant that had been drifting ona collision course with the ice tongue beforebecoming grounded. On 21 February 2005,Drygalski calved an iceberg. The five-by-ten-km(three-by-six mile) iceberg was floating off theleft side of the ice tongue on 22 February whenthis image was acquired. The event is a normal
part of the evolution of the ice tongue—piecesregularly break from the tongue as the glacierpushes more ice out over the sea. This imageshows cracks, formed by time and ocean
currents, which become more numerous to- wards the end of the tongue. Source: NASA 2005, WIKIPEDIA
Huge icebergs are found in Antractica’s regions.These icebergs influence the weather and climaticconditions. It is believed that if these icebergs melt,
the sea levels will rise significantly. The study of thestate of icebergs and their behaviors are very impor-tant aspects of climae change research. Today, multi-
sensored remote sensing data are used in monitoring the state of icebergs. Credit: Michael Van
Woert/UNEP/NOAA
Credit: European Space Agency—ESA
22 Feb 2005
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66
Case Study: Collapse of the Kolka Glacier20 September 2002
Rebecca Lindsey, Olga Tutubalina, Dmitry Petrakov, Sergey Chernomorets
Running east to west across the narrowisthmus of land between the Caspian Seato the east and the Black Sea to the west,the Caucasus Mountains make a physicalbarricade between southern Russia to thenorth and the countries of Georgia and
Azerbaijan to the south. In their center,a series of 5 000-metre-plus (16 000-feet-plus) summits stretch between two extinct
volcanic giants: Mt. Elbrus at the westernlimit and Mt. Kazbek at the eastern. On thelower slopes, snow disappears in July andreturns again in October. On the summit,
winter is permanent. Glaciers cover peaksand steep-walled basins
called cirques. The remote, sparsely populated area is popular with touristsand backpackers.
Elevations reach 5 642 metres (18 511feet), and glaciers accumulate from heavy snowfall in the steep mountain valleys.
Around Mount Kazbek, a dormant volcano,glaciers intermittently collapse, buryingthe landscape below under rock and ice.The latest of such collapses happened in2002. Rebecca Lindsey, science writer withNASA’s Earth Observatory, in close collabo-ration with Russian scientists Olga Tutubali-na, Dmitry Petrakov (Moscow State Univer-sity), and Sergey Chernomorets (University
Centre for Engineering Geodynamics andMonitoring) compiled the details of this event.
On the evening of 20 September 2002,in a cirque just west of Mt. Kazbek, chunks
of rock and hanging glacier on the northface of Mt. Dzhimarai-Khokh tumbled ontothe Kolka glacier below. Kolka shattered,setting off a massive avalanche of ice, snow,and rocks that poured into the GenaldonRiver valley. Hurtling downriver nearly 13
km (8 miles), the avalanche exploded intothe Karmadon Depression, a small bowlof land between two mountain ridges, andswallowed the village of Nizhniy Karmadonand several other settlements.
At the northern end of the depression,the churning mass of debris reached achoke point: the Gates of Karmadon, thenarrow entrance to a steep-walled gorge.Gigantic blocks of ice and rock jammedinto the narrow slot, and water and mudsluiced through. Trapped by the blockage,avalanche debris crashed like waves against the mountains and then finally cementedinto a towering dam of dirty ice and rock,
creating lakes upstream. At least 125people were lost beneath the ice.
The Kolka Glacier collapse partially filled the Karmadon Depression with ice,mud, and rocks, destroying much of the
village of Karmadon. The debris swept inthrough the Genaldon River Valley andbacked up at the entrance to a narrowgorge. The debris acted as a dam, creating
lakes upstream. Boulders, pebbles, andmud covered the surface of the debris flow,resulting in treacherous footing. The path-less maze of debris was only one of many hazards that slowed exploration of thedisaster area.
Scratches on the surface of rocks of theMaili Glacier’s moraine show the violenceof the event. The avalanche, moving upto 180 kilometres per hour (112 mph),scoured the rocks below, leaving parallelgrooves called “striations.” Striations aretypically observed in the bedrock underly-ing glaciers, created by the slow, scouringaction of rocks caught beneath the ice.
Large-scale avalanches and glacial col-lapses are not uncommon on the slopesof Mount Kazbek and nearby peaks. TheKolka Glacier collapsed in 1902, surgedin 1969, and collapsed again in 2002.Evidence, including historical accounts,
indicates similar events have happened inneighboring valleys as well.
After the collapse, people speculatedthat something called a glacial surge hadtriggered the Kolka collapse. In 1902, amore significant collapse at Kolka Glacierkilled 32 people. Despite a history of disas-ters there, routine monitoring of the KolkaGlacier cirque ended in the late 1980s.
NASA Image by Jesse Allen and Robert Simmon based on MODIS data
66
This sequence of images from the Indian Remote Sensing (IRS) satellites showed that the lakes (except LakeSaniba) were draining gradually through crevasses in the ice mass, and were not l ikely to cause subsequent catastrophic floods. Credit: IRS
19 October 2002 22 May 2003 11 July 2003 30 August 2003
Mount Dzhimarai-Khokh, elevation 4 780 metres(15 682 feet), towers above the Kolka Cirque. Rockand ice falling from the steep walls of the cirque sincethe end of July 2002, eventually triggered the collapseof the Kolka Glacier.
13 June 2001
Credit: Olga Tutubalina/UNEP
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The rapidly rising water was a continuingdanger, threatening a sudden outburst that
would cause flooding downstream.Russian researchers evaluated the risk
of future danger at the disaster site using atime-series of satellite images collected inthe year following the disaster. Satellite im-
agery was crucial throughout the late falland winter of 2002 and 2003, when dan-gerous weather prevented on-site observa-tions of the ice-dammed lakes.
Russian scientists combined satellitedata with ground observations to createmaps of the Kolka Glacier Cirque. TheIRS Satellite image (acquired 11 July 2003) shows details of the cirque, includ-ing scars caused by post-collapse rockfall,
a large remnant of the Kolka Glacier, icecliffs high above the floor of the cirque,displaced porous ice, the Maili Glacier, atemporary lake, and deposits of rubble left along the path of the collapsing glacier.
There is uncertainty also about what triggered the collapse of rocks and hang-
ing glaciers on Mount Dzhimarai-Khokh.Two small earthquakes jarred the region inthe months before the collapse, probably destabilized the hanging glaciers. In thefirst days after the collapse, an Emercom(Russian Emergencies Ministry) crew flewto the site via helicopter, but was forced toevacuate immediately when the crew de-tected an overpowering smell of sulfur-con-taining gas. It seems there may be some
fumaroles—volcanic vents—on the face of Mount Dzhimarai-Khokh in the area wherethe hanging glacier collapsed.
Based on the available data and obser- vations, the scientists say they don’t expect any additional catastrophic processes with-in the next 10 to 20 years. The remaining
lakes will likely continue to drain throughcrevasses and channels being cut throughthe ice mass, and as they drain, the risk of flooding decreases.
Published 9 September 2004 Source: http://earthobservatory.nasa.gov/Study/Kolka/ kolka.html
The area covered by ice and debris dwarfed thehamlet of Karmadon, and the Genaldon Riverdisappeared completely. (The outline corre-sponds to the detailed image above.)
Credit: Digital Globe
Credit: Sergey Chernomorets/UNEP
Credit: Olga Tutubalina, Dmitry Petrakov, Sergey Chernomorets/UNEP 25 Sept 2002
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68
Case Study: Arctic Sea Ice
In September 2003, scientists from the UnitedStates and Canada announced that the larg-est ice shelf in the Arctic had broken up. The
Ward Hunt ice shelf to the north of Canada’sEllesmere Island split into two main parts, withother large blocks of ice also pulling away fromthe main sections.
Evidence continues to emerge that averagetemperatures in the Arctic are rising even morerapidly than the global average. Satellite dataindicate that the rate of surface temperatureincrease over the last 20 years was eight timesthe global average over the last 100 years(Comiso 2003).
The edge of the pack ice Source: NOAA Source: Michael Van Woert/UNEP/NOAA
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These images reveal dramatic changes in Arctic sea ice since 1979. The lossof Arctic sea ice may be caused by rising Arctic temperatures that result fromgreenhouse gas build-up in the atmosphere and resulting global warning.
Studies report that the extent of Arctic seaice has shrunk by 7.4 per cent over the past 25
years, with record-low coverage in September2002 (Johannessen et al. 2003). An analysis of 30 years of satellite data suggests that the loss of
Arctic sea ice is also accelerating (Cavalieri et al. 2003). There are projections that much of
the sea ice, until now thought to be permanent, will melt during the summer by the end of thiscentury if the current trend in global warmingcontinues. This will have major direct impactson indigenous people and Arctic wildlife suchas polar bears and seals, and will also openthe region to increased development pressure
as access by sea to valuable natural resourcesbecomes easier. The global impacts may also besignificant as absorption of solar radiation in-creases, and could lead to changes in the worldocean circulation (UCL 2003; NASA 2003;Laxon et al. 2003).
Source: GEO Year Book 2003
Credit: Gyde Lund/UNEP
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70
During much of the 20th century, Iceland’s Breidam
erkurjökull Glacier has been shrinking. It has been
studied extensively since 1903, when researchers d
up detailed maps that showed its base just a fewTUNDRA BREIDAMERKURJÖKULL, ICELAND
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hundred metres from the ocean edge. Over time, the glacier has receded so
that its base is now several kilometers from the coast. As the huge river of
ice has pulled back across the Icelandic landscape, thousands of hectares of
fertile farmland have been exposed and people are populating the area that
was until relatively recently buried under tonnes of ice.
In this pair of satellite images, notice how the glacier has receded and
glacial lake at its tip has enlarged over time. Some researchers attribute t
shrinking of Breidamerkurjökull to climate change and global warming.
scientists maintain that the glacier is simply retreating from the advance
made during the Little Ice Age.
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7272
An ice shelf is a huge sheet of ice that is
grounded on land but has an extension that
reaches out into the ocean. Antarctica has two
great ice shelves: the Ross Ice Shelf near the
Ross Sea and the Filchner Ronne Ice Shelf near
TUNDRA FILCHNER ICE SHELF, A NTARCTICA
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the Antarctic Peninsula. By volume, the Filchner Ice Shelf is the largest
ice shelf on the planet.
In the austral winter of 1986, the front edge of the Filchner Ice
Shelf broke off into the ocean, forming three enormous icebergs
named A22, A23, and A24 by glaciologists. Soon after this calving
event, all three icebergs ran aground on the shallow sea floor just off
shore. In early 1990, however, A24 broke free and moved out into the
open waters of the Weddell Sea, and finally, in 1991, into the southern
Atlantic Ocean. In the 1986 image above, notice how the break line
created when the icebergs calved has filled with sea ice. Sea ice does
not contain the flow lines that are apparent in the glacial ice of the
shelf that lies behind the break line.
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7474
Hubbard Glacier, located at St. Elian National
Park near Yakutat, Alaska, is the largest calving
glacier in North America. It is currently increas-
ing in total mass and advancing across
the entrance of 56-km-long (35-mile-long)
Russell Fjord.
TUNDRA HUBBARD GLACIER , UNITED STATES
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These images show the potential environmental disruption that a
fast glacial flow is capable of producing. In 1986, the Hubbard Gla-
cier blocked the Russell Fjord, endangering seals and porpoises by
producing freshwater runoff that reduced the salinity of that body
of water. Rising water levels also became a concern. By the time the
ice dam eventually broke later that year, the water level of Russell
Fjord had risen by 25 m (82 ft). The images show the Hubbard Glacier
and surrounding area at various stages before, during, and after the
formation of the ice dam.
These photographs show an enlarged eastward-looking view of a small section of the Hubbard Glacierterminus and the evolution of the “squeeze-push” moraine in front of Gilbert Point that blocked the tidalexchange between Disenchantment Bay (bottom of photos) and Russell Fiord (top of photos), creating Rus-sell Lake which rose to 18.6 metres (61 feet) above sea level over 21 ⁄ 2 months before it finally outburst on 14 August 2002, creating the second largest glacial lake outburst worldwide in historical times.
Credit: Unknown/UNEP/USGS, USFS, Yakutat Range District and National Park Service, Yakutat Ranger Station
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7676
Mt. Kilimanjaro, Africa’s highest mountain, is
located 300 km (186 miles) south of the equator
in Tanzania. A forest belt that spans between
1 600 m (5 249 ft) and 3 100 m (10 171 ft) sur-
rounds it. The forest has a rich diversity of eco-
TUNDRA MT . K ILIMANJARO, T ANZANIA
Credit: Christian Lambrechts/UNEP/UNEP-GRID Nairobi
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systems, particularly of vegetation types that result mainly from the
large range in altitude and rainfall of about 700 to 3 000 mm/yr (28
to 118 in/yr). It hosts a very large diversity of species, with about 140
mammal species and over 900 plant species. But of greater concern
are the glaciers atop the mountain. In 1976, glaciers covered most
of the summit of Mt. Kilimanjaro. By 2000, the glaciers had receded
alarmingly. An estimated 82 per cent of the icecap that crowned the
mountain when it was first thoroughly surveyed in 1912 is now gone,
and the remaining ice is thinning as well—by as much as a metre per
year in one area. According to some projections, if recession con-
tinues at the present rate, the majority of the remaining glaciers on
Kilimanjaro could vanish in the next 15 years.
Credit: Christian Lambrechts/UNEP/UNEP-GRID Nairobi
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7878
Since the discovery of oil in Prudhoe Bay,
Alaska, in 1968, the oil industry has dramatically
transformed the former North American Arctic
wilderness. Prudhoe Bay and 18 other oil fields
currently sprawl over more than 2 600 km2
TUNDRA PRUDHOE B AY , UNITED STATES
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(1 004 square miles) in the region. North Slope oil fields now include
3 893 exploratory and producing wells, 170 production and explor-
atory drill pads, 800 km (497 miles) of roads, 1 769 km (1 099 miles)
of trunk and feeder pipelines, two refineries, several airports, and a
collection of production and gas processing facilities, seawater treat-
ment plants, and power plants. These satellite images document the
dramatic changes that the Prudhoe Bay region has undergone over
the past 35 years.
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80
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Hoover, R. (2001). Promises for Power Go Unfulfilled. International RiversNetwork. http://www.irn.org/programs/lesotho/index.asp?id=/pro-grams/lesotho/001031.darkness.html on 31 December 2002; http://www.irn.org/wcd/index.asp?id=/wcd/lhwp.shtml on 16 December 2004.
McKenzie, R. et al. (2000). South African Department of Water Affairs andForestry. http://www.dwaf.gov.za/orange/ on 31 December 2002.
Mochebelele, R. T. (2001). South Africa - Vanderkloof/Gariep Dams, OrangeRiver http://www.dams.org/kbase/studies/za/ on 31 December 2002.
Lake Balkash, Kazakhstan
UNEP (2004). Activities: Sustainable Resource Use – Lake Balkash, Kazakhstan,Guillaume Le Sourd, Diana Rizzolio. UNEP GRID Geneva, Geneva, Swit-zerland. http://www.grid.unep.ch/activities/sustainable/balkhash/index.php on 6 March 2005.
Lake Chad, Africa
FEWS (1997). Famine Early Warning System. Special Report 97-4. http://www.fews.org/fb970527/fb97sr4.html on 31 December 2002.
IMF (2002). International Monetary Fund: Lake Chad Basin Commission(LCBC). http://www.imf.org/external/np/sec/decdo/lcbc.htm on 31December 2002.
International Lakes environment Committee Foundation (1999). World LakesDatabase. http://www.ilec.or.jp/database/afr/afr-02.html on 31 December2002.
JSC (2000). Johnson Space Center Digital Image Collection. http://nsimages. jsc.nasa.gov/images/pao/STS36/10063865.htm on 31 December 2002.
USGS (2001). USGS EarthShots: Satellite Images of Environmental Change.USGS. http://edcwww.cr.usgs.gov/earthshots/slow/LakeChad/LakeChad
on 31 December 2002.
Lake Chapala, Mexico
Campose, Jesus. Personal Communication. CentroGeo, Mexico City, Mexico.
De Anda, Jose, et al. (1998). Hydrologic Balance of Lake Chapala (Mexico). Journal of the American Water Resources Association, Vol. 34, no. 6,December 1998.
Lake Hamoun, Iran
Agrawala, S., Barlow, M., Cullen, H., and Lyon, B. (2001). The Drought andHumanitarian Crisis in Central and Southwest Asia: A Climate Perspective.International Research Institute for Climate Prediction, New York, USA.
Christensen, P. (1993). The Decline of Iranshahr: Irrigation and Environmentsin the History of the Middle East 500 B.C. to A.D. 1500. Museum Tuscula-num Press, University of Co penhagen, Copenhagen, Denmark.
International Federation of Red Cross and Red Crescent Societies (2001).Despair on Iran’s dusty plains, 19 July 2001.
New York Times (2001). Drought chokes off Iran’s water and its economy by Neil MacFarquhar, 18 September 2001.
UN (2001). United Nations Inter-agency Assessment Report on the ExtremeDrought in the Islamic Republic of Iran, by UN Country Team in Iran,
July 2001.
Lake Nakuru, Kenya
Africa Environmental Outlook (2001). Water Quality in Eastern Africa. UnitedNations Environment Programme. http://www.unep.org/aeo/158.htm on31 December 2002.
Forest Department (n.d.). Ministry of Environment and Natural Resources,KIFCON project.
Jones, T. (1993). Lake Nakuru Ramsar Convention Bureau. http://www.ramsar.org/lib_dir_1_3.htm on 31 December 2002.
Lambrechts, C. (2001). UNF, UNEP, KWS, University of Bayreuth, WCST.Personal Communication.
Thampy, R. J. C ase Study: Kenya for the World Wide Fund for Nature (WWF).http://www.aaas.org/international/ehn/biod/thampy.htm on 12 March2005.
Lake Victoria, Uganda
Albright, T., Moorhouse, T., McNabb, T. (2001). The Abundance and Distribu-tion of Water Hyacinth in Lake Victoria and the Kagera River Basin,1989-2001, U.S. Geological Survey, EROS Data Center, Sioux Falls, SouthDakota, USA.
Neuville, G., Baraza, J., Bailly, J., Wehrstedt, Y., Hill, G., Balirwa, J. and Twongo,T. (1995). Mapping of the Distribution of Water Hyacinth Using Satellite
Imagery, Technical Report, RCSSMRS/French Technical Assistance, April1995.
Schouten, L., van Leuwen, H., Bakker, J., Twongo, T. (1999). Water HyacinthDetection in Lake Victoria by Means of Satellite SAR, USP-2 report 98-28,Netherlands Remote Sensing Board, Delft, The Netherlands.
Mesopotamia Marshlands, Iraq
New York Times (2005). http://www.nytimes.com/imagepages/2005/03/07/science/20050308_MARS_GRAPHIC2.html on 28 March 2005.
Partow, H. (2001). The Mesopotamian Marshlands: Demise of an Ecosystem.Division of Early Warning and Assessment. United Nations Environment Programme. Nairobi, Kenya.
USGS (2001). USGS EarthShots: Satellite Images of Environmental Change.http://edcwww.cr.usgs.gov/earthshots/slow/Iraq/Iraq on 31 December2002.
Three Gorges Dam, China
CNEMC (n.d.). Personal Communication and imagery courtesy of Wang Wenjie, China National Environmental Monitoring Center.
Jones, W. C., Freeman, M. (2001). Three Gorges Dam: The TVA on The Yang-tze River Schiller Institute. http://www.schillerinstitute.org/economy/phys_econ/phys_econ_3_gorges.html on 31 December 2002.
NASA (2001). Three Gorges Dam, China Visible Earth. http://visibleearth.nasa.gov/cgi-bin/viewrecord?17955 on 31December 2002.
Tillou, S. L. and Honda, Y. (n.d). Trade and Environment Database. http:// www.american.edu/ted/THREEDAM.htm on 7 January 2003.
Kennedy, B. (2001). China’s Three Gorges Dam. CNN Interactive. http://www.cnn.com/SPECIALS/1999/china.50/asian.superpower/three.gorges/ on7 January 2003.
PBS (n.d). Great Wall across the Yangtze, Public Broadcasting System. http:// www.pbs.org/itvs/greatwall/index.html on 7 January 2003.
Forest
DMZ, Korea (Case Study)
Biodiversity Planning and Support Programme (2001). The Korean Demilita-rized Zone: Eden of Wildlife. Northeast and East Central Asia - NationalBiodiversity Strategies Action Plans, Newsletter, Issue 3/4, 29 March 2001,UNDP – UNEP. http://www.bpsp-neca.brim.ac.cn/newsletter/issue3-4/4.html on 11 March 2005.
Ministry of Environment (n.d.). Republic of Korea. Systematic Conserva-tion for an Eco-Network, Ministry of Environment. http://eng.me.go.kr/user/policies/policies_view.html?msel=b6&seq=7&filename=6_nature_08.html&table_name=me_new_nature on 11 March 2005.
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Midrand Ecocity Project. (n.d.). http://www.midrandecocity.co.za/ on 7 Janu-ary 2003.
Sugrue, A. (2002). Midrand Ecocity of the future. http://www.midrand-ecocity.co.za/overview.htm on 31 December 2002.
Moskva, Russia
UNEP (n.d.) Moscow Integrated Environmental Action Programme, Stateof the Environment in Moscow. http://www.md.mos.ru/eng/comp/c_pr.htm on 25 February 2005.
Bochin, L.A. (1998) Minister of the Moscow City Government for Nature Man-agement and the protection of the Environment, 5 June 1998. http://
www.ourplanet.com/imgversn/95/wed.html on 25 February 2005.
Paris, France
Demographia (2003). Paris Population Analysis and Data Product, 24 March2001. http://www.demographia.com/db-paris-history.htm on 18 February 2005.
Infoplease (2004). Paris, City, France; History. http://www.infoplease.com/ce6/world/A0860241.html 2 March 2005.
MSN Encarta (2005). Paris City, France. http://encarta.msn.com/encyclope-dia_761561798_6/Paris_(city_France).html on 4 March 2005.
Santiago, Chile
Architectural Resources Network (2002). Santiago 1863-1988. http://www.periferia.org/urban/santiago.html on 31 December 2002.
City Net Express (1994). Santiago, Computer Science Department, University of Chile. http://sunsite.dcc.uchile.cl/chile/turismo/santiago.html on 31December 2002.
ICLEI (1999). Sustainable Santiago project report. http://www.cities21.com/iclei/finalrepeng.htm on 31 December 2002.
Luz Alicia Cárdenas Jirón (2001). Urban Form at the Fringe of MetropolitanSantiago. http://revistaurbanismo.uchile.cl/n1/13.html on 31 December2002.
UN Cyber School Bus (2002). Santiago, Chile. http://www.un.org/cyber-schoolbus/habitat/profiles/santiago.asp on 31 December 2002
UNEP (2000). GEO: Chapter Two: The State of the Environment - Latin Ameri-ca and the Caribbean. http://www-cger.nies.go.jp/geo2000/english/0091.htm on 31December 2002.
USGS (2001) USGS Earthshots. USGS. Satellite Images of EnvironmentalChange. http://edc.usgs.gov/earthshots/slow/Santiago/Santiago on 31December 2002.
Sydney, Australia
Essex, Stephen, Chalkley, Brian. Olympic Games: Catalyst of Urban Change.Routledge, part of the Taylor & Francis Group. Volume 7, No. 3 Septem-ber 1998, 187-206.
Australian Government (2001). Dept. of the Environment and Heritage. Hu-man Settlement Theme Report. http://www.deh.gov.au/soe/2001/settle-ments/figures.html on 18 October 2004.
Tripoli, Libya
Country Studies. Population (n.d). http://www.country-studies.com/libya/population.html on 21 March 2005.
UNEP (n.d.). Africa Environment Outlook, Past, Present and Future perspec-tives. http://www.unep.org/dewa/Africa/publications/AEO-1/207.htmon 9 December 2004.
Fedra, K. and Abdel-Rehim, A. (2003). Spatial Analysis for Coastal ZoneManagement: Beyond GIS. Sustainable Management of Scarce Resourcesin the Coastal Zone. http://www.ess.co.at/SMART/kfaafull.html on 9December 2004.
Tundra and Polar Regions
Breidamerkurjökull, Iceland
Iceland (n.d.). http://www.ahojky.net/Pages/Iceland/Iceland%2020Vatnajokull%20Glacier%20Info.htm on 19 February 2005.
Filchner Ice Shelf, Antartica
Ferrigno, J. G. and Gould, W. G. (1987). Substantial changes in the coastlineof Antarctica revealed by satellite imagery: Polar Record, Volume 23, No.146, 577-583.
Korotkov, A. (n.d.). Personal communication. Department of Ice Regime andForecasts, Arctic and Antarctic Research Institute.
Mark F. Meier (1993). Ice, climate, and sea level; do we know what is happen-ing? In: W. R. Peltier, ed., Ice in the climate system: Berlin, Springer-Ver-lag, NATO ASI Series Volume I I2, 141-160.
Oerter, H. (1992). Evidence for basal marine ice in the Filchner-Ronne iceshelf. Nature, Volume 358, No. 6385, 30 July 1992, 3, 399.
USGS (2001). USGS EarthShots: Satellite Images of Environmental Change.http://edc.usgs.gov/earthshots/slow/Filchner/Filchner on 30 December2002; Filchner Ice Shelf, Antarctica. http://edcwww.cr.usgs.gov/earth-shots/slow/Filchner/Filchner on 19 February 2005.
Vaughan, D. (1993). Chasing the Rogue Icebergs. New Scientist, Volume 137,No. 1855, 9 January 1993, 26.
Williams, R.S. Jr. and Ferrigno, J.G. (1988). Satellite image atlas of glaciers of the world; Antarctica: U.S. Geological Survey professional paper, Washing-ton, USA, 1386-B, 278, B103; Stewart 1990, 485.
Hubbard Glacier, USA
USGS (2001). USGS Earthshots. Satellite Images of Environmental Change,8th ed., 12 January 2001, from the EROS Data Center of the U.S. Geologi-cal Survey, a bureau of the U.S. Department of the Interior. http://edc-
www.cr.usgs.gov/earthshots/slow/Hubbard/Hubbard on 31 January 2002.
USGS (2002a). United States Geological Survey Water Resources of Alaska– Glacier & Snow Program. Hubbard Glacier, Alaska. http://ak.water.usgs.gov/glaciology/hubbard/index.htm on 18 March 2005.
USGS (2002b). U.S. Department of the Interior, U.S. Geological Survey. Advancing Glacier Coming Close to Blocking Fjord Near Yakutat, Alaska.http://www.usgs.gov/features/glaciers.html on 18 M arch 2005.
Mount Kilimanjaro, Tanzania
Grimshaw, J. M., C ordeiro, N. J., Foley, C. A. H. (1995). The mammals of Kili-manjaro. Journal of East African Natural History 84, 105-139.
Hemp, A. (2001). Ecology of the pteridophytes on the southern slopes of Mt.Kilimanjaro. Part II: Habitat selection. Plant Biology 3: 493-523.
Lambrechts, C. (2001). Personal Communication. UNF, UNEP, KWS, Univer-sity of Bayreuth, WCST.
Prudhoe Bay, USA
Miller, P. A. (n.d.). The Impact o f Oil Development on Prudhoe Bay, ArcticConnections. http://arcticcircle.uconn.edu/ANWR/arcticconnections.htm on 18 March 2005.
US Fish and Wildlife Service (2001). Potential Impacts of Proposed Oil andGas Development on the Arctic Refuge’s Coastal Plain: Historical Over viewand Issues of Concern. http://arctic.fws.gov/issues1.htm on 23
February 2005.
Credit: Tim McCabe/UNEP/NRCS
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Earthquake Map of the World
Credit: UNEP/USGS GTOPO30, NEIC
Magnitude 7.0 - 7.9 8.0 - 8.9
Major Earthquakes, 1995-2004Western hemisphere
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Major Earthquakes, 1995-2004
Magnitude 7.0 - 7.9 8.0 - 8.9 9.0
The sole 9.0 earthquake shown is the Northern Sumatra earthquake of December 26, 2004.
Eastern hemisphere
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This QuickBird satellite image of Mt. Etna was col-lected on 27 October 2002. This image shows the
volcano as it continued to rage four days after it began erupting. Visible in the far lower-right cornerof the image is the nearby town of Zafferana Etna.Source: UNEP/DigitalGlobe
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4Natural and Human–induced
Extreme Events
Extreme events, whether natural orhuman-induced, can cause signifi-cant environmental change, not to
mention their impacts on peoples’ lives.But many types of natural hazards are alsoexacerbated by environmental degradationcaused by humans. The examples illustrat-ed by the pictures and stories in this chap-ter highlight the links between populationgrowth and distribution, environmentaldamage, and natural disasters. They under-score the need to protect the natural en- vironment of this, our only planet, and tostrengthen its capacity to resist the impact
of both increasing numbers of people anddestructive natural events.
Extreme environmental events, or“natural” disasters, have generally beenregarded as unpredictable and uncontrol-lable “acts of God.” Increasingly, however,it is becoming clear that human activity canaggravate natural events. With a growingpopulation, more people living in hazard-prone regions, and increased environmen-tal degradation, the intensity, frequency,and impacts of natural hazards are alsoheightened. As forests are cut down, wetlands built over, and coral reefs disap-
pear, for example, these ecosystems canno longer function as protective controlson the forces and impacts of hurricanes,floods, and tidal waves. Both the poor,sometimes pushed into vulnerable regionsby economic and political forces, and the wealthy, who build expensive homes wherethey wish, move into disaster prone areasand are affected when natural events occur. With stricter building codes and generally less densely populated settlements, fewerdeaths occur in developed nations thanthey do in developing countries, wherethese events cause very large numbers of
Tornado. Credit: Unknown/UNEP/NOAA
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Lightning Credit: Unknown/UNEP/NOAA
casualties and homelessness. Financiallosses are easier to measure in developedcountries; while the economic ramifica-tions in developing nations may be exten-sive, they are more difficult to calculate.Finally, global climate change resultingfrom human activity is expected to increasethe intensity, frequency, and impacts of weather-related “natural” hazards (UN/ISDR 2004).
Many countries are now engaged indisaster risk reduction and this activity islikely to increase in the wake of the Asiantsunami of 26 December 2004. The scientif-
ic community is making efforts to monitornumerous parametres related to hazard-ous events. By studying and understandingpast events and monitoring on-going ones,
we can glean information that will help tominimize the risk of disaster. While most natural hazards are inevitable, disastersare not (UN/ISDR 2004). Satellite imag-
ery, aerial photography and GeographicInformation Systems (GIS) technology are important tools in monitoring and inproviding early warning information about these natural hazards and the impactsthey may have so that preventive measurescan be taken against impending disasters(UN/ISDR 2004). This chapter includescase studies based on remote sensing data,providing visual examples of each type of extreme event discussed.
Extreme events are hazards that occuras consequences of the impacts of naturalor a human-induced hazard. In this pub-
lication, extreme events are divided intothree categories:
• Geo-hazards: volcanoes, earthquakes,tsunamis, landslides/mudslides;
• Climatic hazards: floods, drought, hur-ricanes, tropical cyclones, tornadoes,ice storms;
• Industrial hazards: oil spills, nuclear,and industrial accidents.
All of these events can expose peopleand ecosystems to danger. Proportionally,they tend to hurt the poor most of all.This is because the poor outnumber therich and live in greater density in more
poorly built housing on land most at risk.They also have fewer resources and capac-ity to prevent or cope with the impacts(UNEP 2002a). The number of disastershas increased more than four-fold sincethe 1960s, from an average of 44 disas-ters a year to an average of 181 disasters a year by the 1990s. Although some of thisincrease may be due to improved report-ing of events, it is likely that the number,severity, and frequency of natural disasters
is increasing. In addition to improvedreporting, the substantial growth in worldpopulation and the increasing vulnerability of marginal groups is a significant factor inthe growth of natural disasters (Kaspersonet al. 2001).
Since 1900, natural hazards have causedover 50 million deaths. Between 1995 and2003, they affected 6 000 million people(some 2 500 million in Asia alone) andcaused over 6 million deaths. Floods af-fect by far the most people (Figure 4.1). While the number of disasters appears tobe increasing, the number of fatalities is
declining. This fact may be attributed toimproved forecasting, better preparedness,and quicker response to disasters. On theother hand, the number of persons af-fected has increased. This is not surprising,given the rapidly growing populations of most developing countries and the millionsof people who depend directly on the natu-ral resources in their immediate environ-ments to sustain their livelihoods. Whenthese resources disappear or are degradedin floods, earthquakes, tsunamis, and otherdisasters, the economies of families and whole communities are devastated.
Economic losses from natural disas-ters have also increased over the past 50 years. Part of this upward trend is linked tosocioeconomic factors, such as populationgrowth in, and migration to, large cities in vulnerable areas, and the increased wealthof some populations that choose to livein hazard-prone areas. Another factor islinked to climate change, such as changesin precipitation and flooding eventsthat destroy property and businesses(OWF n.d.).
Figure 4.1: The number of people affected as aresult of different types of natural hazards between1995 – 2003. Floods were the most destructive haz-ard, followed by droughts, cyclone/hurricane/typhoons and earthquakes. Source: UN/ISDR 2004
Number of people affected due to various
disasters between 1995-2003
Rest
Famine
Cyclone
Drought Flood
Earthquake
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4.1 Geo-hazards Volcanoes A volcano is a vent in the surface of theEarth through which magma and associ-ated gases and ash erupt; also, the wordrefers to the form or structure (usually conical) that is produced by the ejectedmaterial (UND n.d.). Volcanic eruptionsare among the most impressive natural
disasters, due to their unpredictable na-ture, which includes flying debris, streamsof molten lava, emissions of toxic gases,seismic effects, and the many impacts thesehave on the people, animals, and plants intheir way.
About 550 volcanoes have erupted inthe Earth’s recorded history and an equiva-lent number of dormant volcanoes haveonly erupted in the past 10 000 years. Bothdormant and “active” volcanoes have thepotential to erupt again. On any given day,about ten volcanoes are actively erupting(Camp 2000). Explosive eruptions give lit-tle warning, while effusive eruptions, which
send out gently flowing lava, allow time forpeople to escape (Francis 1993).
Of all natural hazards, volcanic erup-tions and earthquakes are the least exac-erbated by human activity. These powerfulevents fit more neatly into the definition of
truly “natural” disasters. Nevertheless, hu-man activity can increase the risk of dam-age caused by such events. For example, volcanic regions are attractive sites becausethe soils are fertile and they provide valu-able minerals, water reservoirs, geothermalresources, and scenic beauty. People be-come more vulnerable when they settle tooclose to active volcanoes. Poor people may
move closer to these potentially dangeroussites as their populations grow and or whenthey have no access to other land. Out of necessity, they may cut trees on volcanoslopes, increasing the danger from lavaflows when they happen (Benson 2002).
A massive volcanic explosion can haveimportant environmental consequencesalso, due to the blast of huge clouds of ash,dust, and gases into the atmosphere. Volca-nic debris in the lower atmosphere falls out or is rained out within days. Volcanic gascan be directly harmful to humans, ani-mals, plants, agricultural crops, and prop-erty. The most common consequence isthe movement of large numbers of peoplefleeing the lava flow.
Environmentally, the hazards from volcanic gases are most severe in the areasimmediately surrounding volcanoes,especially on volcano flanks downwind of
active vents and fumaroles. These hazardscan persist for long distances downwind,however, following large eruptions, or from volcanoes erupting gas-rich magma (Mc-Gee et al. 1997). The resulting veil of pol-lution in the upper atmosphere can havelong-term and geographically extensiveimpacts on climate. Such pollution is in thestratosphere and may remain for several
years, gradually spreading to cover muchof the globe. The particles reflect energy from the sun back into space, preventingsome of the sun’s rays from heating theEarth, thus reducing global warming. TheMount Pinatubo eruption of 1991 was sucha case. An individual eruption may gener-ate global cooling amounting to two orthree tenths of a degree Celsius with effectslasting for a year or two (Kelly 2000; Santeret al. 2001). Millions of tonnes of sulfur di-oxide gas may reach the upper atmosphere where it transforms into tiny particles of sulfuric acid, known as aerosols, that canlead to acid rain (Kelly 2000; CSIRO 2002).
Major eruptions have not been commonthis past century, occurring once every tento twenty years, so the long-term influencehas been slight (Kelly 2000).
Volcano Credit: HVO/UNEP/USGS
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Case Study: Kilauea VolcanoEruption, Kalapana, Hawaii1983-1991
An example of the kind of damage wrought by volcanoes is the eruptionof Kilauea Volcano in Hawaii.Between 1983 and 1990, eruptinglava repeatedly invaded communitiesalong the southern coast of the BigIsland of Hawaii, destroying morethan 180 homes, a visitor center in
Hawaii Volcanoes National Park,highways, and treasured historicaland archaeological sites.Source: USGS 2000; USGS 2002
Maps of lava-flow field from the Pu`u `O`oand Kupaianaha vents of Kilauea Volcano,
Hawaii, January 1983 - January 1991
Orange colour shows areas covered by lavaerupted from Pu`u `O`o between January 1983 and June 1986. Red colour showsareas covered by lava erupted from Kupaia-naha between July and October 1986. Photos by J.P. Eaton. Source: http://hvo.wr.usgs.gov/ kilauea/history/1990Kalapana/#heart
January 1983 - October 1986 January 1983 - December 1986 January 1983 - December 1989 January 1983 - January 1991
23 April 1990 6 June 1990 13 June 1990
These photos show the ecological effects of the erup-tion, including defoliated papaya plants in an orchardat the north edge of the Saefuji orchid farm. The
leaves have been abraded and sheared off by falling pumice from the lava fountain in the background. The
ridge between the orchard and the fountain in the pho-to on the right was formed by the advancing `a`a flow (an Hawaiian term for a type of lava flow that leaves
rough-edged, porous lava). Photos by J.P. Eaton/UNEP/USGS Source: http://hvo.wr.usgs.gov/kilauea/history/1960Jan13
Credit: J.P. Eaton/UNEP/USGS
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Case Study: Eruption of Mount St. Helens18 May 1980
Mount St. Helens is located in the state of Washington on the west coast of the UnitedStates. It is part of the Cascade Range, whichis dominated by periodically active volcanicpeaks. For most of the 20th century, the snow-covered mountain was known for its quiet beauty, until on 18 May 1980, the top 420 m(1 300 ft) disappeared within minutes. Theblast leveled 400 km2 (249 square miles) of
forest, formed a deep horseshoe crater, andsent thousands of tonnes of ash into the upperatmosphere. A major debris flow filled a valley along 24 km (15 miles). Sixty-two people weredead or missing. This eruption of Mount St.Helens was the most destructive in the history of the United States, with total economic lossesestimated at US$1.2 billion (NGDC 2004).
Growth of the new lava dome inside thecrater of Mount St. Helens continues, accom-panied by low rates of seismicity, low emissionsof steam and volcanic gases, and minor pro-duction of ash (USGS 1999). Lessons learnedfrom this and other volcanic activity in the Cas-cade Range will be invaluable to scientists forpredicting such events and anticipating their
ecological impacts (UNEP 2003).
Mount St. Helens and the devastated area is now within the Mount St. Helens National Volcanic Monument,under jurisdiction of the United States Forest Service. Visitor centers, interpretive areas, and trails are be-ing established as thousands of tourists, students, and scientists visit the monument daily. Mount St. Helensis once again considered to be one of the most beautiful and interesting of the Cascade volcanic peaks.Credit: Photograph taken on May 19, 1982. Lyn Topinka/UNEP/USGS Source: Poland 2002
9 Mar 2005 4 Oct 2004
Credit: Space Imaging Credit: Space Imaging
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Earthquakes andTsunamisEarthquake refers to volcanic or magmaticactivity or other sudden stress changes inthe earth. The term is used to describeboth a sudden slip on a fault and theresulting ground shaking and radiatedseismic energy caused by the slip (USGS2002).
Earthquake impacts are many and var-
ied, ranging from minor structural damagein a few buildings to complete devastationover huge areas. The most powerful earth-quakes are capable of annihilating majorurban centers and severely disrupting the
social and economic fabric of nations. Forexample, the Kobe Earthquake of 1995resulted in over 6 000 deaths and estimatesof repair costs in the range of US$95 bil-lion to US$147 billion (EQE 1995).
A tsunami (soo-NAH-mee) is a seriesof extremely long traveling ocean wavesgenerated primarily by underwater grounddisplacement due to an earthquake or vol-canic eruption. In the deep ocean, tsunami waves propagate at speeds exceeding 800
km/h (500 mph). Here, the wave height is only a few tenths of metres(<1 foot ) orless. Tsunamis differ from ordinary ocean waves because of the great distance andtime between wave crests, which are oftenseparated geographically by more than100 km (60 miles) in the deep ocean andin time by 10 minutes to an hour. As they reach the shallow waters of the coast, the waves slow down and the water can pile upinto a wall of destruction. The effect can beamplified where a bay, harbor, or lagoon
funnels the wave as it moves inland. Largetsunamis have been known to rise over 30m (100 ft). Even a tsunami 3–6 m (10–20ft) high can be very destructive and causemany deaths and injuries.
Table 4.1 shows the five largest earth-quakes since 1900 as measured on theRichter scale. Although it is the fifth larg-est, the Banda Aceh earthquake-tsunamithat originated in Indonesia on 26 Decem-ber 2004 affected two continents and led tothe largest number of deaths.
According to long-term records (sinceabout 1900), we can expect about 18 major
earthquakes (7.0 - 7.9 on the Richter scale)and one great earthquake (8.0 or above)in any given year (NEIC 2003). The U.S.Geological Survey, however, estimatesthat several million earthquakes occur inthe world each year. Many go undetectedbecause they occur in remote areas orhave very small magnitudes. The NationalEarthquake Information Center (NEIC)now locates about 50 earthquakes each day,or about 20 000 a year (NEIC 2004). Anincrease in the number of seismograph sta-tions and the more timely receipt of data
has allowed scientists to locate earthquakesmore rapidly and to detect ever-smallerseismic events (NEIC 2003).
The number of earthquakes and tsuna-mis resulting in fatalities has increased ap-proximately in proportion to global popu-lations, and although a decreasing fractionof the global population has been killed by earthquakes in the 20th century comparedto past centuries, seismic risk in certain re-gions has increased substantially. The causeof the apparent paradox lies in the growthof urban agglomerations where most of the world’s growing population will live, andthe location of many of these cities nearplate boundaries where earthquakes occurquasi-periodically (Bilham 1995).
The growth of giant urban cities nearregions of known seismic hazard is a newexperiment for life on the Earth. Withfew exceptions, recent large earthquakes(M>7.5) have spared the world’s majorurban centers. This will not persist indefi-nitely. The recurrence interval for damag-ing earthquakes varies from 30 years to3 000 years; if population densities remain
high in the 21st century, several megacities will be damaged by significant earthquakes(Bilham 1995).
Tsunamis are a threat to life and prop-erty for all coastal residents. There hasbeen massive migration to coastal areas,and today, more than half the world’spopulation lives close to the sea (GlobalOceans 1999). This has caused the rapiddegradation of these areas. As protectivenatural features, such as coral reefs andmangroves, are removed by human de- velopment for tourist hotels and shrimp
Table 4.1 – Five largest earthquakes in the world since 1900
Year Magnitude Country
1960 9.5 Chile1964 9.2 Prince William Sound, Alaska1957 9.1 Andreanof Islands, Alaska1952 9.0 Kamchatka2004 9.0 Banda Aceh, Indonesia
Source: NEIC 2004, http://neic.usgs.gov/neis/eqlists/10maps_world.html
December 30, 2004.
Earthquake destruction Credit: News Photo/UNEP/FEMA
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Case Study: Bhuj Earthquake, India26 January 2001
R. P. Singh, S. Bhoi, A. K. Sahoo
The magitude 7.6 Bhuj earthquake that shookthe Indian Province of Gujarat on the morn-ing of 26 January 2001 was one of the two most deadly earthquakes to strike India in its record-ed history. One month after the earthquake thedeath toll had reached 19 727, and the numberof injured reached 166 000 with at least 600 000 people left homeless. Government esti-
mates placed direct economic losses at US$1.3billion. Other estimates indicate losses were ashigh as US$5 billion. The earthquake brought significant changes to the land and surround-ing ocean water bodies.
The images above show changes in chlo-rophyll concentration prior to and after theearthquake. High concentrations of chloro-phyll, together with high ocean surface tem-perature, are favorable conditions for catchingfish. The significant increase in the fish caught in February around the Gujarat coast after theearthquake was found to be double that of thenormal February fish catch. Source: Singh et al. 2002 Mud volcano observed in Gujarat earthquake of
26 January 2001. Credit: Ramesh P. Singh/UNEP/Indian Institute of Technology, Kanpur
acquaculture farms, for example, so theshoreline becomes increasingly vulnerableto the impacts of wave action and potentialtsunamis. Coastal areas are also increas-ingly at risk due to the effects of burningof fossil fuels; climate change threatens totrigger more powerful storms and raise sealevels, exposing coasts to erosion (Doyle
2004). Global warming, poorly plannedcoastal development, and other threatsover which humans have some control are weakening the coast’s ecological defensesagainst natural disasters.
Of course, tsunamis can cause immea-surable damage to marine and terrestrialecosystems, including coral reefs, man-
groves, and forests. This in turn affectsthe livelihoods of coastal populations whodepend directly on natural resources suchas fish, food from household gardens, andforest products.
A big tentional crack (approximately 30 cm deep)in a nearby field on Bhuj, Khewda. Salt water hadcome up to the surface through the crack due toliquefaction. Credit: Ramesh P. Singh/UNEP/Indian Institute
of Technology, Kanpur
Pre (18 Jan 2001) Post (26 Jan 2001)
1 10 100 (mg m-3)
Chlorophyll Concentration
Case Study: Dust Storms Over ChinaMarch and April 2002
Dust storms are increasing globally with far-reaching consequences for the environment and human health. Severe dust storms canreduce visibility to zero, making travel impos-sible, and can blow away valuable topsoil, whiledepositing soil in places where it may not be
wanted. Drought and, of course, wind contrib-ute to the emergence of dust storms, as do poorfarming and grazing practices. The dust pickedup in such a storm can be carried thousandsof kilometres.
This pair of images, acquired 16 days apart,covers the Liaoning region of China and partsof northern and western Korea. They contrast a relatively clear day (23 March 2002) with onein which the skies were extremely dusty (8 April2002). In the later view (right image), the dust
obscures most of the surface, although theLiaodong peninsula extending between the BoHai Sea and Korea Bay is faintly visible at thelower left. Wave features are apparent withinthe dust layer.
Storms such as this transport mineral dust from the deserts of China and Mongolia overgreat distances, and pollution from agriculture,industry and power generation is also carriedaloft. Thick clouds of dust block substantialamounts of incoming sunlight, which in turncan influence marine phytoplanktonproduction and have a cooling effect onregional climates. Source: NASA n.d.; Planetary Photo
Journal; Wikipedia n.d.; Vince 2004. Credit: Unknown/UNEP/FAO
Satellite images courtesy NASA/GSFC/LaRC/JPI, MISR Team
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Case Study: Indian Ocean Tsunami26 December 2004
On 26 December 2004, an undersea earthquakemeasuring 9.0 on the Richter scale took place inthe Indian Ocean, off the west coast of northernSumatra, Indonesia. It caused one of the deadli-est disasters in recent times. Resulting tsunami
waves crashed into the coastlines of twelvecountries bordering the Indian Ocean, causingmassive losses in human life and infrastructure,and damage to marine and terrestrial ecosys-tems. It is estimated that the tsunami killed morethan 200 000 people, left up to 5 million in needof basic services, and caused billions of dollars of damage.
The effects of the disaster include mas-sive changes in the physical environment. Forexample, it is possible that the ocean depth inparts of the Straits of Malacca, one of the world’sbusiest shipping channels off the coast of Suma-tra, was reduced from about 1 200 m (4 000 feet)to perhaps only 30 m (98 ft), a depth that is tooshallow for shipping (AP 2005).
The island of Trinkat, part of the Nicobar Islands, India, appears to have been cut in half by the tsunami with a new channel of water approximately 5 km (3 miles) long stretching from the settlement of Tapiyang to a point on the opposite coast just west of Ol Ok Chuaka. Another channel has possibly been opened upto the southeast of Takasem separating the large mangrove area from the inhabited northern end of theisland. The mangrove appears to be relatively intact though several inlets have been created in the east.The extensive coral reefs visible along the west and east coasts of Trinkat before the tsunami are largely
obscured by large plumes of sediments presumably washed from the land. The coastline has retreatedalong the east coast enlarging the lagoon. This scouring of terrestrial matter into the lagoon and onto the
reefs could have serious consequences for shallow water habitats if sediments settle for longer periods.Source: UNOSAT
These images are of the southwestern coast of Sri Lanka, taken shortly after the tsunami struck the coastline. The image dated 26 December2004 was taken shortly after the shoreline was struck by the tsunami, while the second image was taken after the ocean returned to normal.Source: http://www.digitalglobe.com/images/tsunami/Sri_Lanka_Tsunami_Damage.
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The city of Banda Aceh, Indonesia, suffered catastrophic damage as a result of thetsunami that struck on 26 December 2004. These QuickBird Natural Colour images on23 June 2000 and on 28 December 2004 (below) clearly show the city before the dev-astation and the extent of the damage after the tsunami. Source: Digital Globe: http://www.digitalglobe.com/images/tsunami/Banda_Aceh_Tsunami_Damage.pdf
23 June 2000
28 Dec 2004
Photo taken in Kulmunai Kuddi on Sri Lanka’s east coast. Credit: Unknown/UNEP/USGS
on Sri Lanka’s east coast.
Cre
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Case Study: Bam Earthquake26 December 2003
Bam is located in the southeastern corner of Ker-man province in Iran. Maintaining its position inthe middle of the southern trade route, this small,fortified city on the outskirts of the vast Dasht-é-Lut Desert is just 350 km (217 miles) west of Paki-stan and 450 km (280 miles) north of the PersianGulf. Eighty-thousand people make their homes
within Bam’s boundaries.
A 6.6 magnitude earthquake struck southeast-ern Iran on 26 December 2003, killing over 40 000
people, injuring 16 000, leaving 70 000 home-less and destroying much of the city of Bam, theearthquake’s epicenter. The quake destroyed theancient citadel of Arg-e-Bam, located on the his-toric Silk Road and thought to be over 2 000 yearsold. This citadel was said to be the largest mudbrick structural complex in the world. Apart fromthe toll on human lives, the loss of this ancient siterepresents an important cultural loss.
Although Iran is subject to frequent largequakes, it does not have strong building codes andbuildings generally do not withstand the impact of these events. As a result, casualties and damage aremuch higher than might be expected from a simi-lar quake elsewhere in the world (The EarthquakeMuseum 2003). Source: NASA 2004e
Credit: Unknown/UNEP/IIEES
Credit: Unknown/UNEP/IIEES
In a region famous for the scarcity of its water, Bam thrived with extensive palm groves and citrus gardens (see images above). Benefiting from sub-terranean water reserves, surfacing through a number of several–km–long water canals, Bam was essentially an agricultural city famous for, and a major producer of, the very best date fruits in all of Iran. After the earthquake of 26 December 2003 that flattened the citadel and the mud-brick houses anddestroyed 85 per cent of the city’s buildings, just about the only things left standing tall above the ruins of Bam were the mainstays of the local economy:
date palms. The date harvests that produced thousands of tonnes of dateseach year were left undamaged in plantation fields and house gardens, of-fering hope for an agricultural-based recovery. Irrigation repairs have begunand agriculturists are optimistic that future date harvests could be as large asthose before the earthquake. Source: USGS n.d.
Healthy Vegetation
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Case Study: Mudslides in California6-11 January 2005
Many days of storms across California in Janu-ary 2005 led to flooding, mudslides, and hugesnowfall totals. On 10 January, a landslidestruck the town of La Conchita in VenturaCounty, destroying or seriously damaging 36houses and killing ten people. It was not thefirst destructive landslide in the area and futurelandslides are likely to occur. The area is a nar-row coastal strip of land between the shorelineand a high bluff above which rises a terrace
covered by avocado and citrus orchards (Jibson2005). Despite the landslide risk, a growing andgenerally wealthy population has expandedinto fragile or risk-prone areas such as these inCalifornia, often building expensive homes likethose destroyed in La Conchita. The popula-tion of Ventura County, for example, grewby five per cent in 2003, from 753 197 in2000 to approximately 790 000 (US CensusBureau 2004).
In the image at right, Multi-satellite Precipi-tation Analysis (MPA) rainfall totals are shownfor the period 6–11 January 2005. The redareas just off of the coast indicate the highest totals of more than 225 mm (about 9 inches) of rainfall. Source: NASA 2005
Landslides and Mudslides Worldwide, thousands of people die every yearfrom landslides and mudslides. In the UnitedSates alone, they cause an estimated US$1 bil-lion in damage and kill 25 to 50 people every
year. Earthquakes, volcanoes, and a number of types of weather events can trigger landslides,
which are characterized by lethal mixtures of water, rocks, and mud. The two largest land-slides in the world in the 20th century occurredat Mount St. Helens, Washington, in 1980 and
at Usoy, Tajikistan, in 1911. Although Mount
St. Helens was the largest landslide recordedin historic time, fewer than 60 people werekilled because most residents and visitors hadbeen evacuated. The Usoy landslide, also trig-gered by an earthquake, moved 2.4 km3 (1.5cubic miles) of material and built a dam 573m (1 880 feet) high (half again as high as theEmpire State Building) on the Murgob River inTajikistan; the dam still impounds a lake nearly 64 km (40 miles) long. This landslide tookplace in a sparsely populated area and thuscaused few deaths (USGS 1999).
The deadliest landslide this century wasalso the result of an earthquake, which occuredin western Iran on 20 June 1990. It caused40 000–50 000 deaths. One of the world’sother major landslides includes the rock andsnow avalanche triggered by a magnitude 7.8earthquake at Mount Huascaran, Peru, on 21May 1970 that buried the towns of Yungay andRanrahirca, killing perhaps as many as 20 000people (NASA 1999).
Mudslide Credit: News Photo/UNEP/FEMA
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Credit: USGS
NASA Earth Observatory: http://earthobservatory.nasa.gov/ NaturalHazards/natural_hazards_v2.php3?img_id=12669 7 February 2005
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Case Study: Landslide CreatesLake in Tibet 2004
Tibet is the major source of Asia’s great rivers.It also has the Earth’s loftiest mountains, the
world’s most extensive and highest plateau, an-cient forests, and many deep valleys untouchedby human disturbance.
In early summer of 2004, a landslide in theZaskar Mountains, a range of the Himalayas,created a natural dam blocking the PareechuRiver in its course from the Tibet Autonomous
Region of China to the Himachal Pradesh Stateof northern India. The dam is 35 km (22 miles)from India’s border with China. The water isslowly building behind the dam, creating anartificial lake in the remote mountain region.By 13 August, the lake had spread over 188hectares and had reached a depth of 35 m (115feet), with water levels rising daily.
The new dam and lake pose a threat to com-munities downstream in northern India. Indianand Chinese officials fear that the unstable dam
will burst, releasing a torrent of water on thesepopulated regions. The remoteness of the areaand the ruggedness of the terrain have preclud-ed preventative measures that could control thepotential catastrophic release of water, although
people have been evacuated from villages inboth the Chinese and Indian parts of the region(NASA 2004a).
These images show the area before thelandslide (top) and the growing lake followingthe landslide (center and bottom) on 15 July 2004 and 1 September 2004. What previously had been a river valley around the meanderingPareechu River on has been entirely covered
with dark blue water.
Satellite images courtesy NASA/GSFC/MITI/ERSDAC/JAROS,and U.S./Japan ASTER Science Team
Source: Zhu Pingyi/UNEP/ICIMOD and RRC-AP
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Flooding Credit: Andrea Booher/UNEP/FEMA
Climatic hazards include storms, floods,heat waves, droughts, and ice storms. Themajority (two-thirds) of all natural disastersare climate or weather-related, principally through drought, flooding, and storms.Furthermore, of all natural hazards, hu-man activity affects weather-related haz-ards the most. With a changing climateinfluenced by the burning of fossil fuels,extreme weather events are projected to in-crease in frequency and/or severity duringthe 21st century (IPCC 2001). Combined with population growth and increasedsettlement in risk-prone areas, the impactsof such events on humans and ecosystems will also increase.
A storm is a low pressure in the atmo-sphere marked by wind and usually by rain,snow, hail, sleet, or thunder and lightning.One of the most violent and destructive isthe cyclone or hurricane.
A tropical cyclone is a large-scale closedcirculation system in the atmosphere above
the ocean with low barometric pressureand strong winds. The winds rotate clock-
wise in the southern hemisphere and coun-ter-clockwise in the northern hemisphere.The system has wind speeds of 119 km/h(73 mph) or more (UN-DHA 1992).
Tropical cyclones are called “hur-ricanes” in the western Atlantic and “ty-phoons” in the western Pacific. Thesedangerous storms can be found in three
of the Earth’s four oceans and in bothhemispheres. Even though Atlantic Oceantropical cyclones (hurricanes) receive a lot of attention, only 12 per cent of tropicalcyclones worldwide are located here. Thenorthwestern Pacific Ocean averages morethan 25 cyclones (typhoons) each year. Another location with great activity is theIndian Ocean. No other part of the worldhas so much activity in such a small area.The Southern Hemisphere also experi-ences tropical cyclones. However, they areconfined to the Western Pacific and IndianOceans (DAS n.d.).
A tropical cyclone’s storm surge is the
most destructive aspect of the storm. It kills the most people, destroys buildings,
and erodes coastal shorelines. Hurricane Andrew, which landed in south Florida in1992, was the most expensive cyclone todate, causing US$25 billion in property damage and killing 26 people. The cyclonethat caused the highest mortality in the20th century was an unnamed typhoonthat struck Bangladesh in 1970, killingabout 300 000 people.
Scientists predict that global warming will cause warmer ocean temperaturesand associated increased moisture in theatmosphere—two variables that work topower hurricanes. As a result, more intensehurricanes that cause even more damage when they hit land are predicted (Hender-son-Sellers et al. 1998).
Tropical cyclones also cause flooding. A flood is a significant rise of water level ina stream, lake, reservoir, or coastal region(UN-DHA 1992). Human actions can causeor contribute to flooding events throughthe impacts of dams, levees, the removal of
wetlands (that store water), deforestation(resulting in erosion), and other means.
4.2 Climatic Hazards
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Case Study: Supercyclone hits eastern India29 October 1999.
On 29 October 1999 a supercyclone with winds in excessof 257 km/h (160 mph) swept in from the Bay of Bengalto hit the eastern state of Orissa, India. An estimated 15million people were left homeless by the storm, whichhad a death toll as high as 10 000.
Coastal areas of Orissa were hard hit by the supercyclone. The oval outline encloses majorareas affected by this supercyclone. Source: Maps of India, 2004. http://www.mapsofindia.com/maps/mapin- news/22101999.htm July 18, 2004
Supercyclone approaching Orissa coast, India, October 1999
Case Study: Hurricane Charley August 2004
Hurricane Charley developed from a tropical wave that emerged off the African coast early in August 2004. It hit the western tip of Cubaand by the time it reached the greater Havanaarea, maximum sustained winds were nearly 165 km/hr (105 mph). Western Cuba sufferedmore than US$1 billion in property damageand three people died.
The map above shows Charley’s pathbetween the 9th and 14th of August 2004 as it traveled up from the Caribbean into Floridaand the southeast United States. The mapshows Multi-satellite Precipitation Analysis(MPA) rainfall totals for the period. A swath of 7–12 cm (3–5 in) rainfall (green area) extendsfrom the central Gulf of Mexico into northernFlorida as a result of Tropical Storm Bonnie,
which landed in Florida on the 12th of August.
A heavier swath of rain containing 7–25 cm(3-10 in) amounts (darker red areas) extendsfrom the north central Caribbean up throughCuba across Florida and merges with a heavy rain area along the Carolina coast.
In Florida, 25 of the state’s 67 counties
were declared federal disaster areas. Estimatedinsured losses from Charley were US$7 bil-lion, while total economic loss was estimated at nearly US$15 billion. Charley was blamed for22 deaths.
Despite its history of hurricanes, Florida’s warm weather and beaches attract migrants,retirees, and tourists. Florida’s population grewby 6.5 per cent between 2000 and 2003 (U.S.Census Bureau 2004). In some coastal areas,tourists and “snow birds” (northern Americansand Canadians who spend the winter in thesouth) swell populations by 10 to 100 fold.Large parts of densely populated coastal areas
are subject to the inundation caused by hurri-cane storm surges and on numerous occasionshave experienced heavy economic losses fromthese events (NOAA n.d.). Source: NASA 2004b,http://earthobservatory.nasa.gov/NaturalHazards/natural_haz- ards_v2.php3?img_id=12339, NASA 2004b
Hurricane Charley blew ashore over Punta Gorda,Florida, on 13 August 2004, with winds topping 233 km/hr (145 mph). Two days later, the Ikonossatellite captured the top image above. The imageshows the destruction the Category 4 hurricane
wrought on the coastal city. Debris is scattered acrossroads, parking lots, and yards, giving the scene a“messy” appearance compared to the crisp, neat neighborhoods shown in the lower image, takentwo years earlier on 28 July 2002. Source: NASA 2004b,http://earthobservatory.nasa.gov/Newsroom/NewImages/images.
php3?img_id=16639
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02
Floods Worldwide, the number of major flooddisasters has grown significantly, from 6cases in the 1950s to 26 in the 1990s. Withthe changing climate, global precipitationhas increased by about two per cent since1900; during this time, rain patterns havechanged, with some places becoming wet-ter and others, such as North Africa southof the Sahara, drier (Cosgrove 2003).
From 1971 to 1995, floods affectedmore than 1 500 million people worldwide,or 100 million people per year. In the most calamitous storm surge, the flood in Ban-gladesh in April 1991 killed thousands of people. The United Nations estimates that by 2025, half the world’s population willbe living in areas at risk from storms and
other weather extremes (Cosgrove 2003).
Major flood events around the world in 2003 and 2004 (updated through September 2, 2004) Data Source: DFO 2004, http://www.dartmouth.edu/%7Efloods/Archives/index.html
Case Study: Flooding in Mozambique2000 and 2001The years 2000 and 2001 saw massive flood-
ing in Mozambique, particularly along theLimpopo, Save and Zambezi valleys. In 2000half a million people were made homelessand 700 lost their lives. The floods destroyedcrops and overwhelmed water and sanitationinfrastructure in many areas.
Southern Mozambique bore the fullimpact of the rains and rising waters. In the
capital, Maputo, tens of thousands of people were forced to flee their homes. The worst hit were people living in makeshift homes in
the slums around the capital. Maputo, thecapital city of one million, was literally iso-lated as a result of the floods, and entry intothe city was impossible.
Further north, hundreds of thousandsof people were left homeless in Gaza prov-ince. Roads, homes, bridges and crops weredestroyed. Electricity supplies were disruptedand towns left without clean water suppliesafter their pumping stations were swept away.
These two images show an area in Mo-zambique before the onset of flooding andduring flooding. The 2000 image revealsa large area around the towns of Vila DeChibuto and Guija submerged under flood
water from the Limpopo River. Source: BBC 2000,
Oxfam 2001, FEWS Net 2001. Satellite image: Kwabena Asante–SAIC-USGS National Center for EROS.
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Credit: Philip Wijmans/UNEP/ACT-LWF Trevo Credit: Philip Wijmans/UNEP/ACT-LWF Trevo
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Case Study: Severe Flooding in Haiti andthe Dominican Republic23 – 25 May 2004
Several days of heavy rains in late May 2004 caused rivers to overflowin areas near the southern border between the Dominican Republicand Haiti. Heavy rains in this region of deforested hillsides gener-ated rapid run-off and severe flooding. Floods and landslides devas-tated large areas of the island of Hispaniola, which the two countriesshare. The flooding demolished entire communities, caused massiveloss of life, displaced tens of thousands of people on both sides of the border, and resulted in sizeable crop and livestock losses.
These maps (left) compare the topography of Hispaniola (top) with the island’s population density (bottom). The flood disaster area around the Massif de la Salle
is outlined in blue. Source: Flood disaster hits Hispaniola, NASA 2004c
Credit: Cpl. Mike Escobar/UNEP
Tropical storm Jeanne struck the Island of Hispaniola on 18 September 2004; a wall of water and mud buried much of Gonaïves, Haiti as shown in this Ikonosimagery captured four days later, on 22 September 2004. Roads visible on 17 Sep-tember 2000 image have disappeared, as have a number of buildings and adjacent farmlands submerged by water and mud. Note the damaged ship and changesin the water colour in the 22 September 2004 image. Credit: Ikonos imagery provided on spaceimaging.com, courtesy of NASA’s Earth Observatory
17 September 2000
22 September 2004
These two Landsat images (below) contrast the two time periods during and afterthe floods. In the 12 May 2004 image, most of the region is covered by water(grayish colour) while the 26 September 2004 image water has receded, leaving behind green healthy vegetation especially in the area south and east of Gonaives.Source: NASA Earth Observatory
Flooding as a result of this hurricane is blamed for over 3 000 lives lost,including 2 826 in the coastal city of Gonaïves, Haiti (USAID 2004).
Haiti, which is the poorest country in the Americas, has a populationof about 8 million and is prone to deadly floods because 98 per cent of its forests have been chopped down, largely to make charcoal for cooking(Sustainable Institute 2004).
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04
Drought A drought is a period of dryness, especially when prolonged, that causes extensivedamage to crops or prevents their suc-cessful growth. Droughts are often causedby heat waves. A heat wave is a period of unusually hot weather. High temperaturesexacerbate the effects of drought, dam-
age crops and their establishment, andreduce yields (FAO 1996). Climate change will potentially increase the likelihood of droughts in dry and semi-arid regions.There is already evidence that a numberof such regions have experienced declinesin rainfall. Droughts result in decreases insoil fertility and agricultural, livestock, for-
est, and rangeland production. They alsoexacerbate the process of desertification.(IPCC 2001).
Throughout history, various parts of theglobe have suffered drought and subse-quent famine, resulting in huge humani-tarian and economic losses.
Drought Credit: Somkiat Sirvi/UNEP/Topfoto
Case Study: Lake Mead–Drought in
the Western United States2003
The western half of the United States hassuffered a sustained drought over the past several years, which has caused withering
vegetation, more frequent and severe forest fires, and falling water levels in major reser-
voirs throughout the region.
This image of Lake Mead, Nevada, dra-matically captures the result of decreasedrainfall and snow in the western UnitedStates. As of 2003, water levels at Lake Meaddropped 18 m (60 ft). Lake Mead is formedby the Hoover Dam and is an important wa-ter source for the states of Arizona, Nevada,
and California. About 25 million people livein the region and the lake supplies over 80per cent of Las Vegas’ drinking water. Popula-tion growth, the building of water-hungry golf courses, and the needs of irrigatedagriculture in the region are taxing its waterresources, however. Las Vegas is the country’sfastest growing city and Nevada is its fastest growing state. Although temperatures in theLas Vegas Valley rise to 32ºC (90ºF) or moreon more than 125 days of the year and it receives less than 1 000 mm (39 in) of rain a
Credit: Lynn Betts/UNEP/NRCS
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year, Las Vegas has the highest per-capita con-sumption of water in the world (UNEP 2002b).
The combined effect of drought, popu-lation growth, unsustainable development,and climate change in this arid region of theUnited States could be a recipe for more disas-trous droughts and potential conflict. Recently,conservation awareness campaigns and water–use restrictions have helped to lower water use,despite the addition of more than 60 000 newresidents in 2003 (SNWA 2004). Source: Images and text by NASA’s Earth Observatory
Brilliant green golf course fairways contrast sharp-ly against the drought-stricken landscape of theBoulder Basin. Despite the region’s third-worst drought in recent history, new courses continue tobe developed. Source: UNEP/GRID - Sioux Falls
The image to the right, acquired by the Landsat 7satellite, shows the shoreline of Lake Mead inMay 2000.
Water levels in the lake during the 3-year-spanillustrated by the 2001, 2003, and 2004 imagesdropped 18 m (60 ft). In the Boulder Basin of LakeMead, the lower water level has connected formerislands like Saddle Island to the shoreline. Source: UNEP/GRID - Sioux Falls
Credit: Lynn Betts/UNEP/NRCS
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Case Study: Drought in Kenya January 2005
In Kenya, one of the countries inthe Horn of Africa, drought hasbeen looming for several years,leaving many regions of the coun-try parched and hungry. As the2004/2005 harvest drew to a close,the cereal deficit grew to 300 000metric tonnes, which meant that up
to 2.7 million people needed foodaid that season—an unusually highnumber for Kenya. The second maizecrop, scheduled to be harvested in March, was predicted to be 20 per cent belowaverage because of a lack of rain. The 2005 shortages stem from a lack of rainfallduring the short rainy season, which normally runs from November to January.Though some parts of Kenya received adequate rain, crop-growing regions inthe Eastern, Central, and Coast Provinces received far-below-average rainfall. InCentral Province alone, about 400 000 people face famine, according to govern-ment estimates. Source: NASA 2004d, http://earthobservatory.nasa.gov/Newsroom/NewImages/images.
php3?img_id=16816
Case Study: Drought in Horn of Africa
What makes drought in the Horn of Africa an issue of global interest is itsperennial recurrence and its extensive humanitarian impact. Poor agriculturalpractices and environmental degradation (catchments degradation) havegreatly compounded the problem leading to serious food crises in the region.In 1984 and 1985, the Horn of Africa experienced one of the worst droughtsof the twentieth century with a resultant famine that killed 750 000 people.
This Normalized Difference Vegetation Index (NDVI) image to the right shows the vegetation anomaly for August 1984. Dark red indicates the most severe drought, light yellow areas are normal, and green areas have denserthan normal vegetation. Source: NASA 2000, www.m-w.com, http://earthobservatory.nasa.gov/Li- brary/DroughtFacts/
Case Study: Drought in Australia2002-2004
After Australia’s devastating drought in 2002,the 2003/2004 season saw record wheat andbarley harvests, with the March crop up 119per cent compared to the previous year’sdrought-stricken crop.
This pattern of large harvests afterdrought-stunted years is common. To recouptheir losses, farmers increase the area they sow. In 2002, pasture land for livestock was so
parched and the price of grain so high, that many farmers sold their livestock and con-
verted their land to crops in 2003. In additionto the increase in cropland, well-timed rains inmost parts of the country, particularly in West-ern Australia, combined to produce a bumperharvest that year. Source: NASA 2003
The difference between the two years is clearly visible in this image pair of the southwestern point of Aus-tralia, showing the expanded crop area. A larger portion of Western Australia is covered with greener vegeta-tion in September 2003, right, compared to September 2002, a sign that all plants, including grain crops, were thriving in 2003. Source: NASA 2003, http://earthobservatory.nasa.gov/NaturalHazards/natural_hazards_v2.php3?img_id=12010
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The impact of drought on the crops can be seenin this image, which shows the Normalized Differ-ence Vegetation Index (NDVI) anomaly for Kenya
as measured by the Moderate Resolution Imag-ing Spectroradiometer (MODIS) during the first two weeks of January 2005. NDVI is a measure of
vegetation density and health. The anomaly imagecompares current conditions to average condi-tions in 2001, 2002, 2003, and 2004 during the first
two weeks of January. Between 1-16 January 2005,brown clusters in the Coast and Eastern provincesshow patterns of dryness where vegetation is less
dense than it has been in the past. More pro-nounced drought areas surround Central Province.Grey pixels indicate regions where data were not
available. An arch of green through the center of the country reveals where rainfall was plentiful and vegetation is thriving.
Credit: Unknown/UNEP/African Wildlife Foundation
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Oil spill Credit: Khan Kuyucu/UNEP/Topfoto
Industrial hazards are threats to peopleand life-support systems that arise fromthe mass production of goods and services(Mitchell 1996). They can be intentionalactions, such as the illegal discharge of oil into the environment, or accidental,such as toxic spills. Like natural hazards,they can expose people and ecosystems to
danger, affecting lives, health, and socio-economic conditions (Draffan 2004).
One of the major industrial disastersoccurred in Bhopal, killing at least 14 400people and causing permanent disabili-ties to at least 50 000 others. In the early hours of 3 December 1984, gas leakedfrom a tank of methyl isocyanate (MIC),resulting in intense emission of toxic gasesat a plant in Bhopal , India, owned andoperated by Union Carbide India Limited(UCIL). This event is considered to bethe worst chemical accident in history. InFebruary 1989, the Supreme Court of In-dia directed Union Carbide Corporation
(UCC) and UCIL to pay a total of US$470million in full settlement of all claims aris-ing from the tragedy.
Oil spillsFossil fuels (oil, natural gas, and coal)account for the vast bulk of global energy supplies. These fuels, formed over mil-lions of years, are finite and non-renew-able. Population growth and increasedaffluence and consumption increase thedemand for fuel. In due course, these
resources will become scarce and costly,requiring the introduction of replacement energy sources (MacKenzie 2000). In addi-tion, disputes over their ownership already occur and there is significant potential forincreased conflict.
Petroleum is an integral part of ourlives. It provides 80 per cent of the world’stransportation fuel, supplies nearly half the world’s primary energy demand, andprovides feedstock for the petrochemicalindustry. Petroleum products account forabout a third of global oil use today.
The exploration for, development,
transportation, and use of petroleumcauses environmental problems world- wide. The most critical issue today is that
fossil fuel burning emits gases that con-tribute to global climate change (Cohen1990). Oil spills, the focus of this section,can harm life by poisoning, by direct con-tact, and by destroying habitats, especially in the marine environment.
As shown in Figure 4.2, about 37per cent of oil in the world’s oceans is
the result of urban and industrial runoff.
Another seven per cent is oil which seepsnaturally out of fissures in the sea beds. About 14 per cent is caused directly by the
Figure 4.2: Sources of oil in the world’s oceans.The highest contribution (about 37 per cent)results from urban run-off and the discharge fromland-based industrial plants. These materials reachthe sea via storm-water drains, sewage outfalls,creeks, and rivers. Souce: APPEA n.d.
4.3 Industrial Hazards
12%
9%
37%
33%
7%
2%
Land runoff
Discharge
Natural seepage
Oil exploration
Tanker spills
Atmosphere
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oil industry, of which 12 per cent is fromaccidents involving oil tankers. In the U.S.,pipelines now spill considerably more thantankers. Another 33 per cent is the result of discharges to the environment and theremaining nine per cent of oil depositedin the oceans is absorbed from the atmo-sphere (APPEA n.d.).
As evident from Table 4.2, oil spills hap-pen all around the world. Oil spills of at least 38 m3 (125 cubic feet) have occurred
in the waters of 112 nations since 1960.The top four “hot spots” for oil spills from vessels include the Gulf of Mexico (267spills); the northeastern U.S. (140 spills);the Mediterranean Sea (127 spills); and thePersian Gulf (108 spills) (Etkin 1997).
Despite overall increases in oil trans-port, the numbers of marine oil spills andthe amount spilled have decreased signifi-cantly over the last two decades, particular-ly in the last few years. The average num-
ber of large spills per year during the 1990s was about a third of that witnessed duringthe 1970s (ITOPF 2003). This decrease canlikely be attributed to reduced accident rates due to preventive measures and in-creased concerns over escalating financialliabilities (Etkin 2001).
Table 4.2 – Major oil-related industrial accidents between 1970-2004
Year Location Industry Loss/description
1976 Massachusetts, USA Oil spill Argo Merchant runs aground on the Nantucket Shoals off Cape Cod (MassachusettsUSA), spilling 29 million litres (7.6 million gallons) of No. 6 fuel oil.
1978 France Oil tanker Amoco Cadiz tanker runs aground off the coast of France, spilling 1.6 million barrelsof crude oil.
1984 Cubatao, Brazil Oil pipeline Oil fire - 508 deaths
1988 Piper Alpha, North Sea Oil rig 167 deaths from explosion of offshore oil platform
1989 Alaska, USA Oil tanker Exxon Valdez tanker spills 42 million litres (11 million gallons) of crude oil intoPrince William Sound (Alaska USA)
1994 Seoul, S. Korea Oil fire 500 deaths
1995 Taegu, S.Korea Oil & gas explosion 100 deaths
1998 Warri, Nigeria Oil pipeline Pipeline at Jesse, Nigeria exploded, instantly killing more than 500 people andseverely burning hundreds more. Up to 2 000 people had been lining up with bucketsand bottles to scoop up oil. The fire spread and engulfed the nearby villages of Moosqar and Oghara, killing farmers and villagers sleeping in their homes.
2000 Adeje, Nigeria Oil pipeline 250 deaths
Source: Compiled from Mitchell and Cutter 1997, Anon. 2004, Draffan 2004, and Uranium Information Centre Ltd. 2004
Case Study: Gulf WarKuwait and Persian Gulf 23–27 January 1991
During the Persian Gulf War, Iraq deliberately released 908–1 741 million litres (240–460 mil-lion gallons) of crude oil from tankers into the
Persian Gulf 16 km(10 miles) off Kuwait. Oilspilled onto more than 1 287 km (800 miles) of Kuwait and Saudi Arabian beaches, devastatingmarine wildlife, especially birds (Krupa 1997).
The Persian Gulf war brought about someof the worst environmental pollution everrecorded as a result of oil spills and oil fires.
In the images, the blue shows water, greenshows natural vegetation, light yellow showsdesert areas and black shows pollution from oilspills and fire.
Credit: UNEP/GRID–Sioux Falls
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Nuclear Accidents With increasing concern over poten-tial energy shortages and the impactsof burning fossil fuels, the debateabout nuclear power has been re-newed. Like hydroelectricity genera-tion, nuclear power has the merit of being a clean energy source in termsof emissions, however, there are risksassociated with the release of danger-
ous radiation from potential nuclearmeltdown and from nuclear waste.
Between 1940 and 2000, there wereat least 120 notable accidents involvingnuclear material. These ranged froma container of uranium hexafluorideexploding in Oak Ridge, Tennessee, inthe United States in 1944 killing twopeople and injuring three others tothe worst accident in the history of thenuclear power industry – Chernobyl,Ukraine in 1986 (Anon n.d.).
Case Study: Chernobyl Nuclear PowerPlant Accident, Ukraine25-26 April 1986
The world’s worst nuclear power accident oc-curred at Chernobyl in the former USSR (nowUkraine) on 25-26 April 1986. While testinga reactor, numerous safety procedures weredisregarded and a chain reaction resulted inexplosions and a fireball, which blew off thereactor’s heavy steel and concrete lid. Theexplosion and fire released radioactive mate-
rial that spread over parts of the Soviet Union,Eastern Europe, Scandinavia, and later, West-ern Europe. The Chernobyl accident killedmore than 31 people immediately, and as aresult of the high radiation levels in the sur-rounding 32–km (20–mile) radius, 135 000people had to be evacuated. Some areas wererendered uninhabitable for years. As a result of the radiation released into the atmosphere,tens of thousands of excess cancer deaths (as
well as increased rates of birth defects) wereexpected in succeeding decades (Anon. n.d.).
The 31 May 1986 image was acquired about a month after the nuclearaccident at Chernobyl’s Reactor Number 4. The Chernobyl nuclear plant is located on the northwest shore of a cooling pond. Much of thefarmland surrounding the plant was heavily contaminated with radioactive nuclides and subsequently abandoned. The areas have changedfrom red and white patterns indicating planted agricultural fields andbare soil in the 1986 image to tan-gray tones indicating natural vegeta-tion in the 1992 image. More than 120 000 people from 213 villagesand cities were relocated outside the contamination zone. Pripyat, anabandoned city with a 1986 population of 45 000, is located 3 km (2miles) northwest of the Chernobyl Nuclear Power Station. The wavy white line north of the Chernobyl plant in the 1992 image is a leveebuilt to prevent the flow of contaminated water and soil into the Pripyat River. Source: Earthshots 2001; Sadowski and Covington 1987; Stebelsky 1995; Mould 1988; Medvedev 1990; Williams 1995; Schmidt 1995; Park 1989; Marples 1996.
The lines overlaid on the 1992 image show the approximate extent of Ce-sium-137 radiation levels according to 1990 data. Locations within the solidred lines have radiation levels greater than 40 Curies per km2, too high forlife, and this area has been almost completely abandoned by people.
Credit: Elena/UNEP
Credit: Unknown/UNEP/Ukrainianweb
Credit: Warren Gretz/UNEP/NREL
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Andean glaciers have long been involved in numerousavalanches, which have caused considerable materiallosses and casualties by the thousands. The events of 1962 and 1970, originating from Mt. Huascarán’s north-ern summit, were particularly deadly. On 31 May 1970,Y UNGAY CITY , PERU
A VALANCHE
Images of the avalanche that covered Yungay City.Credit: UNEP/Servicio Aereofotográfico Nacional, Lima, Perú
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a 7.7 magnitude earthquake triggered a huge avalanche, 25 km (16miles) long and moving at 280 km/h (174 mph), which wiped out thecity of Yungay, claiming 18 000 lives. The scars are still visible today.Ice retreat has induced the formation of numerous peri-glacial lakes,
dammed only by fragile moraine deposits. Subject to erosion, the walls may collapse, triggering flash floods—another threat for thelocal population.
�
Credit: Walter Silverio September, 1997/UNEP
Almost nothing remains of Yungay City, literally erased by the 1970 avalanche.
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Located in southern Senegal is a feature that appears tobe a meteor-impact-generated structure, possibly mil-lions of years old. It is a circular, multiple ring struc-ture with an overall diameter of 48 km (30 miles) andcentered about 12 km (7 miles) south-southwest of thetown of Velingara.
The inset depicts elevation using radar data acquiredfrom Space Shuttle Endeavour in February 2000. TheShuttle Radar Topography Mission provides science
with a window of understanding previously unknown inareas such as Velingara, Senegal. Notice how the lightercolored(lower) elevations reflect the water features seen
in the Landsat images. The dark ring reveals the higherelevations that enclose the basin.
V ELINGARA , SENEGAL
METEOR I MPACT
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The high rim structure of the Velingara Crater encloses the AnambeBasin. Water previously flowing out the south end of the basin was har-nessed behind a dam in the mid-1970s as a source of irrigation for riceand other crops. The 1975 image predates the irrigation development.
By 2001 intense agricultural systems had appeared near the center ofthe crater(right image), contrasting sharply with the swampy areas (dgreen) nearby. The Velingara Crater was first detected using Landsat in the early 1970s.
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Sadowski, F.G., and Covington, S.J. (1987). Processingand analysis of commercial satellite image data of thenuclear accident near Chernobyl, U.S.S.R. Washington,USA, USGS Survey Bulletin 1785, 10,19.
Santer, B. D.; Doutriaux, C.; Boyle, J. S.; Taylor, K. E.; Wigley, T. M. L.; Meehl, G. A.; Hansen, J. E.; Jones, P.D.; Roeckner, E. ;Sengupta, S. (2001). Accounting forthe Effects of Volcanoes and ENSO in Comparisons of Modeled and Observed Temperature Trends. Journalof Geophysical Research-Atmospheres, November 2001.http://www.cgd.ucar.edu/cas/abstracts/files/Wig-ley2001_3.html on 12 April 2004.
Schmidt, K.F. (1995). The truly wild life around Chernobyl:U.S. News and World Report, 17 July 1995, 51-53.
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Singh, R.P.; Bhoi, S.; Sahoo, A.K. (2002). Changes Ob-served on Land and Ocean after Gujarat Earthquake of January 26, 2001 using IRS Data, International Journalof Remote Sensing, Volume 23, No. 16, 3123 – 3128.http://home.iitk.ac.in/~ramesh on 16 August 2004.
SNWA (2004). Southern Nevada Water Authority, Drought Handbook. http://www.snwa.com/html/wr_drought_handbook.html on 8 March 2005.
Stebelsky, I. (1995). Radionuclide contamination and settle-ment abandonment around Chernobyl: Annals of the Association of American Geographers, v. 85, 1995, 291.
Sustainability Institute (2004). Within Limits: News of Over-shoot. Sustainability Institute, Hartland, Vermont, USA.http://www.sustainabilityinstitute.org/limits/overshoot.html on 10 March 2005.
The Earthquake Museum (2003). Reports on Recent MajorEarthquakes. http://www.olympus.net/personal/gofam-ily/quake/2003quakes.html on 8 March 2005.
Ukrainian Web (n.d.): http://www.ukrainianweb.com/im-ages/chernobyl/chernobyl_reactor.jpg on 10 February 2005.
UN-DHA (1992). International agreed glossary of basicterms related to disaster management. United Nations,Department of Humanitarian Affairs, InternationalDecade for Natural Disaster Reduction, Geneva, Switzer-land, 83. http://www.cred.be/emdat/Guide/glossary.htm on 13 April 2004.
UN-ISDR (2004). Living with Risk - A global review of disas-ter reduction initiatives
2004 version. United Nations Inter-Agency Secretariat of the International Strategy for Disaster Reduction,Geneva, Switzerland. http://www.unisdr.org/eng/about_isdr/bd-lwr-2004-eng.htm on 1 August 2004;http://www.unisdr.org/eng/about_isdr/basic_docs/LwR2004/ch1%20Section%201.pdf on 1 August 2004.
UND (n.d.). The cost of volcanic eruptions. University of North Dakota, Grand Forks, North Dakota, USA.http://volcano.und.nodak.edu/vwdocs/vw_hyperex-change/CostVolc.html on 12 April 2004; Volcanic andgeologic terms. http://volcano.und.nodak.edu/vw-docs/glossary.html on 12 April 2004.
UNL (n.d.). The Southwestern U.S Drought of 2003. SomeHydrological Impacts. University of Nebraska-LincolnHigh Plains Regional Climate Center, Lincoln, Ne-braska, USA. http://www.hprcc.unl.edu/nebraska/sw-drought-2003.html on 9 March 2005.
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USAID (2004). Flooding in Haiti & the Dominican Repub-lic. http://www.usaid.gov/haiti/floods.html on 9 March2005.
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Silverio, W. (1999). Essai d’évaluation des instabilités depente par un système d’information géographiqueet leur interprétation dans la région de Huascarán,Département d’Ancash, Pérou, MSc thesis in Analysisand Management of Geological Risk, University of Geneva, 65.
Meteor Impact Velingara, Senegal
Master, S., Diallo, D.P., Kande, S., and Wade, S. (1999). The Velingara Ring Structure in Haute Casamance, Senegal: A Possible Large Buried Meteorite Impact Crater. Dept.of Geology, Univ. of the Witwatersrand, P. Bag 3, WITS2050, Johannesburg, South Africa. http://www.ulrich-
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NASA (2000). Exploration: Impact Craters. http://liftoff.msfc.nasa.gov/Academy/SPACE/SolarSystem/Mete-ors/Craters.html on 7 March 2005.
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Credit: Tan Kok Lian/UNEP/Topfoto
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The history of the human race is filled withstories of ingenuity regarding our ability to har-ness the bounty of nature. Wind powered thesailing ships of explorers, wood and coal fueled
railroads that threaded across our continents,and now petroleum fires the engines of ourcars and airplanes and allows us to spread to allcorners of the planet.
The goods and services from nature havesustained us, moved us, and inspired us. Ourcultural heritage was shaped by the vast bounty of the Earth. Our ever-increasing demandfor more of nature’s goods has left a series of huge footprints—footprints visible from distant points in space. These footprints represent theplaces we live and work, the places where wegain food, fiber, and minerals, and the ribbonsof transportation needed by our highly mobilesocieties to conduct our businesses.
As this volume illustrates in colorful and
graphical ways, our successes may also beour failure. We have advanced our civiliza-tions by conquering nature. As a people, weshould respect what we have accomplished.However, we must ultimately ask ourselves thequestion—“have our efforts to tame the Earthensured our permanence?” The evidence inthe atlas suggests that our victories over natureare incomplete because in the course of our de-
velopment, we have depleted our resources andcontaminated our environment to the point
where our future may be one full of struggles
and challenges as we try to access ever moreprecious commodities from nature on which wedepend.
To survive, we must put the era of nature
conquest behind us and embark on a new era—the sustainability and stewardship era. In thisera, we must cleanse our air and water so that it supports life in the future. We must serve andrenew our natural resources so that we have thefood, fiber, and energy we need, and we must protect and preserve our remaining naturalareas so that they can soothe our spirits andinspire our minds.
In W.L. Thomas’s seminal volume on sus-tainable development published in 1956, Ken-neth Boulding closed the dialog by providingthe following point-counterpoint. He suggest-ed that the moral of human exploitation of theEarth’s resources was “The evolutionary plan
went astray by evolving man.” Boulding then
offered the perspective of developers by writing“man’s a nuisance, man’s a crackpot, but only man can hit the jackpot.”
Which perspective is right? From the van-tage of space, we can clearly see our footprintson the Earth and we can over time see theexpanding size and number of footprints. Ourspecies can take pride in the complex patternsof our cities and farms as these demonstrateour ingenuity and industriousness. Our num-bers have grown dramatically yet we can argue
that the overall quality of life has improved. At least on the surface... For while it appears that
we have conquered nature, a closer look at theconsequences of our footprint reveals the rest
of the story. The Earth’s environmental systemsare changing fast—and maybe too fast. Theimpacts of our industriousness are changing asfast or maybe even faster than the pace of ourfootprints. The frequency of extreme events,such as droughts, floods, severe storms, and
wildfires is accelerating faster than ever re-corded. Our climate is changing more rapidly than ever before, and the rate of species extinc-tion is going up at an alarming rate. From the
vantage of space, we can see the footprints of the human race. Unfortunately, by the time wesee those footprints, it may already be too latebecause the undesirable impacts of ouractions are already spreading through theEarth’s environment.
Boulding’s message was simple: Sustainthe Earth, keep it healthy, and make it thriveso that it continues to provide for the many people that use it as home. The view fromspace suggests that we have a lot of work aheadto tailor our behavior so that the Earth providesbounty for eons. And there’s no time likethe present to get started on the pathto sustainability.
EpilogueOne Planet Many People
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The Conservationist’s Lament
The world is finiteResources are scarceThings are bad
And will be worseCoal is burnt
And gas explodedForests cut
And soils eroded Wells are drying Air’s polluted
Dust is blowingTrees uprootedOil is goingOres depletedDrains receive
What is excretedLand is sinkingSeas are risingMan is farToo enterprisingFire will rage
With man to fan it Soon we’ll have
A plundered planet People breed
Like fertile rabbitsPeople haveDisgusting habits
MORAL...
The evolutionary plan Went astray By evolving Man
The Technologist’s Reply
Man’s potentialIs quite terrific
You can’t go backTo the NeolithicThe cream is thereFor us to skim it Knowledge is power
And the sky’s the limit Every mouthHas hands to feed it
Food is found When people need it All we needIs found in graniteOnce we haveThe men to plan it
Yeast and algaeGive us meat Soil is almost ObsoleteMan can growTo pastures greenerTill all the earthIs Pasadena
MORAL...Man’s a nuisance Man’s a crackpot But only man Can hit the jackpot
Kenneth Boulding in: Thomas, W.L. ed. 1956. Man’s Role in Changing the Face of the Earth.
Chicago: University of Chicago Press.
Credit: Thomas Lang/UNEP/Topfoto
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AAAS American Association for the Advancement of Science
ACT Action by Church Together
AER Agriculture Economic Research Service, United StatesDepartment of Agriculture
AEZ Agro-ecological Zones
AMS American Meteorological Society
AP Associated Press
APPEA Australian Petroleum Production and Exploration Association Ltd.
Ar Argon
ASTER Advanced Spaceborne Thermal Emission andReflection Radiometer
BBC British Broadcasting Corporation
BP British Petroleum
BRIDGE BRinging Information to Decision-makers forGlobal Effectiveness
Btu British thermal units
ºC degree Centigrade
CFCs Chlorofluorocarbons
CH3Cl Methyl chloride
CH4 Methane
CIDA Canadian International Development Agency CIESIN Center for International Earth Science
Information Network
CIS Commonwealth of Independent States
CITEPA Inter-professional Technical Centre for Researchinto Air Pollution
CLIRSEN Center for Integral Surveys of Natural Resourcesusing Remote Sensing (Ecuador)
cm Centimetres
CNPPA Commission on National Parks and Protected Areas
CO Carbon monoxide
CO2 Carbon dioxide
CPI Center-pivot irrigation
CSIRO Commonwealth Scientific and Industrial ResearchOrganisation
CSR Climatological Solar RadiationDAS Department of Atmospheric Sciences - University of
Illinois at Urbana-Champaign
DETR Department of Environment, Transport andRegions (United Kingdom)
DEWA Division of Early Warning and Assessment
DFO Dartmouth Flood Observatory
DMZ Demilitarized Zone
DMS Defense Meteorological Satellite Program
DPRK Democratic People’s Republic of Korea
EEA European Environment Agency
EIA Energy Information Administration, United StatesDepartment of Energy
ENSO El Niño/Southern Oscillation
EPA Environmental Protection Agency
EQE European Quality & Environment
EROS Earth Resources Observation and Science(National Center)
ERSDAC Earth Remote Sensing Data Analysis Center
ESA Department of Economic and Social Affairsof the United Nations
ETM Enhanced Thematic Mapper ( ETM+).
FAO Food and Agriculture Organisation of theUnited Nations
FEMA Federal Emergency Management Agency
FEWS Famine Early Warning Systems
FOEE Friends of the Earth Europe
ft Foot/Feet
GEF Global Environment Facility
GEO Global Environment Outlook
GEO3 Global Environmental Outlook Report 3(UNEP Publication)
GHG Greenhouse Gas
GIS Geographic Information System
GLC Global Land Cover
GLCF Global Land Cover Facility
GPS Global positioning system
GPW Gridded Population of the World
GRID Global Resource Information Database
GSFC Goddard Space Flight Center (NASA)
H2O Hydrogen dioxide
HEAVEN Healthier Environment through the Abatement
of Vehicle Emissions and Noise
HFCs Hydrofluorocarbons
HNO3 Nitric acid
hPa Hecto pascals, a unit for atmospheric pressure
IIASA International Institute for Applied Systems Analysis
IAEA The International Atomic Energy Agency
ICE Inventory of Conflict and Environment
IIEES International Institute of Earthquake Engineeringand Seismology
IITK Indian Institute of Technology Kanpur
IPC International Programs Center, United StatesCensus Bureau, Population Division
IPCC Intergovernmental Panel on Climate Change
ISDR International Strategy for Disaster Reduction
ITOPF International Tanker Owners PollutionFederation Limited
IUCN International Union for Conservation of Natureand Natural Resources
JAMS Japanese Association of Mathematical Sciences
JAROS Japan Resources Observation System Organization
KBG Kara-Bogaz-Gol, Turkmenistan
kcal kilocalories
kg kilogrammes
km kilometres
km/h kilometers/hour
km2 square kilometres
kWh Kilo-watt hours
KWS Kenya Wildlife Service
lb pounds
LDCs Least Developed Countries
LHWP Lesotho Highlands Water Projet
LLDCs Landlocked Developing Countries
LP DAAC Land Processes Distributed Active Archive Center
LPG Liquefied petroleum gas
LUT Land Utilization Types
LWF Lutheran World Federation
M Magnitude
m metres
MDG Millennium Development Goals
MEA Multilateral Environment Agreement
METI Ministry of Economy Trade andIndustry (Japan)
MIC Methyl Isocyanate
MISR Multi-angle Imaging SpectroRadiometer
mm millimetres
MODIS Moderate Resolution Imaging Spectroradiometer
MOPITT Measurements of pollution in the troposphereinstrument aboard NASA’s Terra satellite
MPA Multi-satellite Precipitation Analysis
Acronyms and Abbreviations
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MRS Metropolitan Region of Santiago
MSS Multispectral scanner
Mt. Mount
n.d. Not dated
N2 Nitrogen
N2O Nitrogen dioxide
NASA National Aeronautics and Space Administration
NCAR The National Center for Atmospheric Research
NCPPR National Center for Public Policy Research
NCR&LB National Contractor Referrals and License Bureau
NDVI Normalized Difference Vegetation Index
NEIC National Earthquake Information CenterNOAA National Oceanic and Atmospheric Administration
NOx Nitrogen oxides
NREL National Renewable Energy Laboratory
NRCS Natural Resources Conservation Service
NRDC Natural Resources Defense Council
NSIDC National Snow and Ice Data Center
NSW EPA New South Wales Environmental
Protection Authority
NWT Northwestern Territories
O2 Oxygen
O3 Ozone
OECD Organisation for Economic Co-operationand Development
OWF Our World FoundationPBS Public Broadcasting System
PFCs Perfluorocarbons
RFD Reasonably Foreseeable Development
ROK Republic of Korea
RRC-AP Regional Resource Centre for Asia and the Pacific
SAIC Science Applications International Corporation
SARCS Southeast Asian Regional Committee for START
SCOPE Scientific Committee on Problems on theEnvironment
SBSTTA Subsidiary Body on Scientific, Technicaland Technological Advice
SF6 Sulphur hexafluoride
SIDS Small Island Developing StatesSIDA Swedish International Development
Cooperation Agency
SIO Scripps Institution of Oceanography
SNHP Spanish National Hydrological Plan
SNWA Southern Nevada Water Authority
SO2 Sulfur dioxide
SPRI Scott Polar Research Institute
SRM Society for Range Management
SWERA Solar and Wind Energy Resource Assessment
TBR Transboundary Biosphere Reserve
TM Thematic Mapper
TOMS Total Ozone Mapping Spectrometer
TSSC Technical Support Services ContractorUCC Union Carbide Corporation
UCIL Union Carbide India Limited
UCL University College London
UCS Union of Concerned Scientists
UGRB Upper Green River Basin
UN United Nations
UND University of North Dakota
UN-DHA United Nations, Department of Humanitarian Affairs
UNDP United Nations Development Programme
UNDRO United Nations Disaster Relief Organization
UNEP United Nations Environment Programme
UNESCO United Nations Educational, Scientificand Cultural Organization
UNF United Nations Foundation
UNFCCC United Nations Framework Conventionon Climate Change
UNFPA United Nations Population Fund
UNHCR United Nations High Commissioner for Refugees
UN-ISDR United Nations Inter-Agency Secretariat of the International Strategy for Disaster Reduction
UPI United Press International
USAID United States Agency for
International Development USCCSP United States Climate Change Science Program
USDA/FAS United States Department of Agriculture/Foreign Agricultural Service
USF University of San Francisco
USGS United States Geological Survey
USSR Union of Soviet Socialist Republics
UTC Universal Time
UV Ultraviolet
VOCNM Volatile organic compound (non-methane)
VOC Volatile organic compound
WCMC World Conservation Monitoring Centre
WCST Wildlife Conservation Society – Tanzania
WHO World Health Organiation WMO World Meteorological Organization
WRI World Resources Institute
WWF World Wildlife Fund
WWF/DCP World Wildlife Fund/Danube-CarpathianProgramme
ETM/LANDSAT Equipped with high resolution instruments, Landsat- 7 was success-fully launched on 15 April 1999. This satellite carries the Enhanced Thermal Mapper Plus(ETM+), which is an eight-band, multispectral scanning radiometer. The ETM+ is capableof resolving distances of meters in the panchromatic band; 30m (98 feet) in the visible, nearand short-wave infrared band; and 60m (197 feet) in the thermal infraredband.
LANDSAT On 23 July 1972, NASA launched the first in a series of satellitesdesigned to provide repetitive global coverage of the Earth’s land masses. It was designatedinitially as the ‘Earth Resources Technology Satellite-A’. The second in this series of Earthresources satellites (designated ‘ERTS-B’) was launched on 22 January 1975. It was renamed‘Landsat 2’ by NASA, which also renamed ‘ERTS-1’ as ‘Landsat 1’. Four additional Landsats
were launched in 1978, 1982, and 1999 (Landsat 3, 4, 5 and7), respectively.
SCANSAR Scanning synthetic aperture radar (ScanSAR) data is acquired onboard the Canadian satellite RADARSAT-1. The RADARSAT-1 satellite was launched on 4November 1995 and has been providing imagery for operational monitoring services on aglobal basis ever since. The state-of-the-art Synthetic Aperture Radar (SAR) can be steeredto collect data over a 1 175 km (730 miles) wide area using 7 beam modes. This provides us-ers with superb flexibility in acquiring images with a range of resolutions, incidence angles,and coverage area.
IKONOS Since its launch in September 1999, Space Imaging’s IKONOS earthimaging satellite has provided a reliable stream of image data. IKONOS produces 1-meterblack-and-white (panchromatic) and 4-meter multispectral (red, blue, green, near infrared)imagery that can be combined in a variety of ways to accommodate a wide range of high-resolution imagery applications.
QUICKBIRD The QuickBird satellite, launched in October 2001on a Boeing DeltaII rocket from Vandenberg Air Force Base, California, is the first in a constellation of spacecraft that DigitalGlobe® is developing. QuickBird offers sub-meter resolution imagery,geolocational accuracy, and large on-board data storage. QuickBird’s global collection of
panchromatic and multispectral imagery is designed to support applications ranging frommap publishing to land and asset management to insurance risk assessment.
PHOTOS Africa Focus; African Wildlife Foundation; Beth Allen; Bigfoto (www.bigfoto.com); Canadian Auto Workers (CAW); Chandra Giri; Christian Lambrechts; Cpl.Mike Escobar; David McKee; David P. Shorthouse; Digital Globe; Dmitry Petrakov; EdSimpson; Elena; FEMA; Freefoto (freefoto.com); FAO; Gray Tappan; H. Gyde Lund; HassanPartow; International Centre for Integrated Mountain Development (ICIMOD); IIEES;Invasive.org; Jim Welch; John Townshend; José de Jesús Campos Enrîquez; J .P. Eaton; JuanSchlatter; Claudio Donoso; Lorant Czaran; Lumbuenamo Raymond; Lyn Topinka; LynnBetts;Morgue File (www.Morguefile.com), DT Creations, Kevin Connors; NASA; NOAA;NREL; NRCS; Nik Wheeler; Olga Tutubalina; Peter Aengst; Peter Bardos-Déak, Philip
Wijmans; Prof. Dr.-Ing.habil. Volker Quaschning; Ramesh P. Singh; Randy Cyr; RegionalResource Centre for Asia and Pacific (RRC-AP); Saman Salari Sharif,; Sergey Cherno-morets ; Servicio Aerofotográfico Nacional, Lima, Perú; Simon Tsuo; South Florida WaterManagement District; Stephan Volz; Teal H.F. Smith; Topfoto (http://www.topfoto.co.uk/);Topham Photos; Ukrainianweb; UNEP-GRID; USGS; USDA; United States National ParkService; V. Sahanatien; Walter Silverio.
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UNEP would like to thank the following for their contributions to One Planet Many People: Atlas of
Our Changing Environment :
Jonathan M. Adams, Department of Biology,Providence College, United States
Robert G. Bailey, United States Department of
Agriculture Forest Service, United StatesElgene Box, University of Georgia, UnitedStates
Robert Campbell, South Dakota School of Mines and Technology, United States
Ellen Carnevale, Population Reference Bureau,United States
Glenn Carver, Centre for Atmosphere Science,University of Cambridge, United Kingdom
Cyrille Chatelain, Conservatoire du JardinBotanique, Switzerland
Sergey Chernomorets, University Centre forEngineering Geodynamics and Monitoring,Russia
Lorant Czaran, United Nations, New York
Paul Davis, University of Maryland, UnitedStates
Timothy Foresman, International Center forRemote Sensing Education, United States
Johann G. Goldammer, Freiberg University,Germany
David Herring, Earth Observatory, UnitedStates
Jean-Michel Jaquet, University of Geneva andUnited Nations Environment Programme,Global Resources Information Database, Swit-zerland
Satya P. S. Kushwaha, Forestry & Ecology Divi-sion, Indian Institute of Remote Sensing, India
Rebecca Lindsey, Science Systems and Appli-cations, Inc., National Aeronautics and Space
Administration, United States
Luisa Maffi, Terralingua, Canada
Martha Maiden, National Aeronautics andSpace Administration, United States
James W. Merchant, University of Nebraska– Lincoln, United States
Eleanore Meredith, Earth Satellite Corpora-tion, United States
Roger Mitchell, Earth Satellite Corporation,United States
Erika Monnati, Italy
Sumith Pathirana, Southern Cross University, Australia
Dmitry Petrakov, Moscow State University,Russia
Volker Quaschning, University of Applied Sci-ences, Germany
Navin Ramankutty, Center for Sustainability and the Global Environment, Institute for En-
vironmental Studies, University of Wisconsin-Madison, United States
Era Singh, United States
Ramesh Singh, Indian Institute of Technology Kanpur, India
Leena Srivastava, The Energy and ResourcesInstitute (TERI), India
Woody Turner, National Aeronautics and Space Administration, United States
Olga Tutubalina, Moscow State University,Russia
Antoinette Wannebo, Center for InternationalEarth Science Information Network, Columbia
University, United States
Wang Wenjie, Intergraph Mapping and Geospa-tial Solutions, China
Wesley Wettengel, World Wildlife Federation,United States
Ben White, University of Maryland, UnitedStates
From the United States Geological Survey, National Center for Earth Resources Observation and Science,United States:
Ron Beck
John Faundeen
Tom Holm
Rachel Kurtz Janice Nelson
From Science Applications International Corpora- tion, contractor to the United States Geological Sur- vey, National Center for Ear th Resources Observation and Science, United States:
Kwabena Asante
Roger Auch
Jon Christopherson
Jeff Danielson
Chandra Giri
Nazmul Hossain
Rynn Lamb
Lee McManus
Sandra Prince
James Rowland
Pat ScaramuzzaG. Gray Tappan
From the United Nations Environment Programme, Division of Early Warning and Assessment:
Johannes Akiwumi, Kenya
Dan Claasen, Kenya
Jesper Koefed, Kenya
Christian Lambrechts, Kenya
Dominique del Pietro, GRID – Geneva
Hassan Partow, GRID – Geneva
Pascal Peduzzi, GRID – Geneva
Walter Silverio, GRID – Geneva
Nicole Strub, GRID – Geneva
Tin Aung Moe, Thailand
Visiting scientists or interns at the United Nations Environment Programme, Global Resources Informa- tion Database - Sioux Falls, United States:
Daniel Amamoo-Otchere, Ghana
Lily-Rose Maida Awori, Kenya
Abdullah Daud, Bangladesh
José de Jesüs Campos Enríquez, Mexico
Ragna Godtland, United States
Shingo Ikeda, Japan
Alfa N. Isiaku, Nigeria
John Molefe, Botswana
Elitsa Peneva, Bulgaria Anup Prasad, India
S.K. Puri, India
Anil Raghavan, India
Ryan Reker, United States
Hua Shi, China
Shalini Venkataraman, Singapore
Special thanks goes to the Global Land Cover Facil- ity (GLCF) of the University of Maryland and the National Aeronautics and Space Administration
(NASA) Earth Observatory for providing access to satellite data.
Acknowledgements
Map Credits:
Topographic Map of the WorldThis image of the world was generated with data from the Global 30-arc second elevation(GTOPO30) dataset. The image is in the Orthographic Projection (Eastern hemispherecentered on 20 north latitude, 65 east longitude; Western hemisphere centered on 15 northlatitude, 75 west longitude) commonly used for maps of the world. Elevation data usedin this image were acquired by the SRTM aboard the Space Shuttle Endeavour, launchedon 11 February 2000. The mission is a cooperative project between NASA, the NationalGeospatial-Intelligence Agency (NGA) of the U.S. Department of Defense and the Germanand Italian space agencies. It is managed by NASA’s Jet Propulsion Laboratory, Pasadena,California, for NASA’s Earth Science Enterprise, Washington, DC, USA. http://www2.jpl.nasa.gov/srtm/world.htm on 28 December 2004.
Nightlight Map of the World
This image of Earth’s city lights was created with data from the Defense MeteorologicalSatellite Program (DMSP) Operational Linescan System (OLS). Originally designed to
view clouds by moonlight, the OLS is also used to map the locations of permanent lights onthe Earth’s surface. Data courtesy Marc Imhoff of NASA GSFC and Christopher Elvidge of NOAA NGDC. Image by Craig Mayhew and Robert Simmon, NASA GSFC. http://visiblee-arth.nasa.gov on 30 December 2002.
Daylight Map of the World
NASA Goddard Space Flight Center Image by Reto Stöckli (land surface, shallow water, andclouds). Enhancements by Robert Simmon (ocean color, compositing, 3D globes, anima-tion). Data and technical support: MODIS Land Group; MODIS Science Data Support Team; MODIS Atmosphere Group; MODIS Ocean Group Additional data: USGS EROSData Center (topography); USGS Terrestrial Remote Sensing Flagstaff Field Center (Ant-arctica). http://visibleearth.nasa.gov on 30 December 2004.
Earthquake Map of the World
The earthquake map was produced by overlaying earthquake data (major earthquakes,1995-2004), shown as dots of varying sizes depending on magnitude on the Richter scale,over a global elevation map produced from the Global 30-arc second elevation (GTOPO30)dataset. The earthquake data are from the U.S Geological Survey National EarthquakeInformation Centre, http://neic.usgs.gov/ on 15 February 2005. The GTOPO30 data arefrom the National Center for Earth Resources Observation and Science. http://edcdaac.usgs.gov/gtopo30/gtopo30.html on 15 February 2005.
8/8/2019 Atlas of Our Changing Environment (ONU-United Nations Environment Programme 2005)
http://slidepdf.com/reader/full/atlas-of-our-changing-environment-onu-united-nations-environment-programme 332/332
Index
Aerosol 81
Africa 3, 80, 85, 96
Africa, Lake Chad 140-141
Africa, Mozambique 302
Agriculture 4, 5, 6
Agro-Ecological Zones 26 Amazon 81, 159
Antarctic 74-75, 95, 260-263
Antarctica, Filchner Ice Shelf 272-273
Antarctica, Ninnis Glacier 263
Arctic 74, 76, 260-263
Arctic Sea Ice 268-269
Asia 38, 39, 262
Atmosphere 69, 72-86
Australia 9, 39, 306
Australia, Sydney 24, 254-255
Australia, Weipa Bauxite Mine 60-61
Australia, Wyperfeld National Park 226-227
Avalanche 310-311
Bangladesh, Dhaka 240-241
Biocultural Diversity 21
Biodiversity 33, 35-37, 69, 72
Biological Diversity 13, 35-37
Biomass 46
Bolivia, Santa Cruz 206-207
Brazil, Brazilia 236-237
Brazil, Para 159
Brazil, Rondônia 26, 184-185
Breidamerkurjökull 79, 270-271
Brunei Darussalam 85
Cambodia, Phnom Penh 110-111
Canada 40, 44
Canada, Ekati 54-55
Canada, British Columbia 166-167
Canada, Knife River Delta 108-109
Carbon dioxide 6, 46, 77
Central America 80, 303
Central America, Haiti 303
Cereal 6
Chile, Escondida 52-53
Chile, Santiago 252-253
Chile, Valdivian 190-191
China 40, 86, 295
China, Beijing 234-235
China, Huang He Delta 102-103
China, Three Gorges Dam 152-153Climate 2
Climate Change 34, 72, 79-81
Coal 46
Coastal Areas 90-115, 294-295
Coral Reefs 91, 94, 95
Côte D’Ivoire, Tai National Park 188-189
Crops/Cropland 5, 13, 28, 69, 192-213
Crude birth rate 16-17
Crude death rate 17
Culture 3, 6, 13, 21-24
Czech Republic 82
D.R. of the Congo, Kisangani 174-175
Daylight Map of the World 64-65
Deforestation 14, 26, 27, 77
Degradation 8, 28-29, 33, 72
Demilitarized Zone 160Demographic Transition Model 17-18
Desertification 29-31, 37
Deserts 4
Dominican Republic 303
Droughts 29, 304-306
Drygalski Ice Tongue 265
Dust storms 295
Earthquake 2, 294-297
Earthquake Map of the World 86-87
Ecoregions 32-34
Ecosystem 21, 32-33, 35, 69
Ecuador, Gulf of Guayaquil100-101
Egypt, Toshka Project 212-213
Endangered 33
Energy Consumption 43-44
England, London 81
Europe 28, 38, 79, 82, 262
Europe, The Black Triangle 48-49, 82
European Union 21
E-waste 68
Extreme Events 289-313
Finland, Lappi 176-177
Fire 2-3
African Fires 85
Amazon Fires 159
Rodeo-Chediski Fires 158
Floods 302-303
Forests 13, 28, 29, 36, 69, 81, 156-191
Boreal Forest 164, 176, 186, 190
Subtropical Forest 162, 170,172
Temperate Forest 166, 178
Tropical Forest 68, 168, 174, 180,
182, 184, 188
Fragmentation 37
France, Paris 83, 250-251
Freshwater Ecosystems and wetlands 69
Gambia, Banjul 232-233
Geo-hazards 291
Geothermal 46
Germany 82Glacier 263
Global vegetative cover 2
Global warming 34, 72, 74-80, 295
Grasslands 13, 28, 36, 40, 214-227
Greece 6
Greenhouse gasses 46, 68, 74, 77, 79, 85
Greenland 260-162
Guatemala/Mexico, Country Border 168-169
Gulf of Mexico 93
HEAVEN 83
Himalayas, Gangotri Glacier 264
History 1-9
Mesolithic Period 3-4
Neolithic Period 4-5
Paleolithic Period 3-4
Honduras, Gulf of Fonseca 98-99Horn of Africa 306
Hotspots 40
Human Footprint 67
Hurricane 301
Hydroelectric 46
India 34, 238-239, 295, 301, 307
India, Arunachal Pradesh 42
India, Bhuj 295
India, Delhi 238-239
India/Bangladesh, Sundarban 112-113
Indian Ocean 296
Indian Subcontinent 80, 295
Indonesia 85
Indonesia, Papua 182-183
Industrial hazards 307-309
Invasive Species 37-39
Iran 297
Iran, Bam 297
Iran, Lake Hamoun 144-145
Iran, Tehran 19
Iraq 5
Iraq, Mesopotamia 5, 9, 150-151
Iraq/Iran, Shatt al-Arab 196-197
Japan, Isahaya Bay 106-107
Jordan 5
Jordan, Dead Sea 1, 130-131
Kazakhstan, Aral Sea 124-125
Kazakhstan, Lake Balkhash138-139
Kenya 306
Kenya, Lake Nakuru 146-147
Kenya, Lake Victoria 20
Kenya, Narok 218-219
Kilauea Volcano 292
Kipini Conservancy, Africa 96
Kuwait 308
Landslides 298-299
Land-use 5, 25, 26, 30
Languages 21-23
Laos, Oudomxay 180-181
Lesotho Highlands Water Project 136-137Libya, Tripoli 256-257
Life Expectancy 16-17
Madagascar, Itampolo172-173
Malaysia 85
Mangroves 91
Mediterranean 95, 308
Meteor 2, 312-313
Methane 77, 78
Mexico 38
Mexico, Angangueo 162-163
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